and and Norton J. Lapeyrouse CONTENTS

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1 and and Norton J. Lapeyrouse CONTENTS

2 Chapter 1 Basic Formulas P Pressure Gradient Hydrostatic Pressure Converting Pressure into Mud Weight Specific Gravity Equivalent Circulating Density Maximum Allowable Mud Weight Pump Output Annular Velocity Capacity Formula Control Drilling Buoyancy Factor 12. Hydrostatic Pressure Decrease POOH Loss of Overbalance Due to Falling Mud Level Formation Temperature Hydraulic Horsepower Drill Pipe/Drill Collar Calculations Pump Pressure/ Pump Stroke Relationship Cost Per Foot Temperature Conversion Formulas Chapter 2 Basic Calculations P Volumes and Strokes Slug Calculations Accumulator Capacity Usable Volume Per Bottle Bulk Density of Cuttings (Using Mud Balance) Drill String Design (Limitations) Ton-Mile (TM) Calculations Cementing Calculations Weighted Cement Calculations Calculations for the Number of Sacks of Cement Required Calculations for the Number of Feet to Be Cemented Setting a Balanced Cement Plug Differential Hydrostatic Pressure Between Cement in the Annulus and Mud Inside the Casing Hydraulicing Casing Depth of a Washout Lost Returns Loss of Overbalance Stuck Pipe Calculations Calculations Required for Spotting Pills Pressure Required to Break Circulation Chapter 3 Drilling Fluids P Increase Mud Weight Dilution Mixing Fluids of Different Densities Oil Based Mud Calculations Solids Analysis Solids Fractions Dilution of Mud System Displacement - Barrels of Water/Slurry Required Evaluation of Hydrocyclone Evaluation of Centrifuge Chapter 4 Pressure Control P Kill Sheets & Related Calculations 1

3 Pre-recorded Information Kick Analysis Pressure Analysis Stripping/Snubbing Calculations Sub-sea Considerations Work-over Operations Chapter 5 Engineering Calculations P Bit Nozzle selection - Optimised Hydraulics Hydraulics Analysis Critical Annular Velocity & Critical Flow Rate D Exponent Cuttings Slip Velocity Surge & Swab Pressures Equivalent Circulating Density Fracture Gradient Determination - Surface Application Fracture Gradient Determination - Sub-sea Application Directional Drilling Calculations Miscellaneous Equations & Calculations Appendix A P. 157 Appendix B P. 164 Index P

4 CHAPTER ONE BASIC FORMULAS 1. Pressure Gradient Pressure gradient, psi/ft, using mud weight, ppg 3

5 psi/ft = mud weight, ppg x Example: 12.0 ppg fluid psi/ft = 12.0 ppg x psi/ft = Pressure gradient, psi/ft, using mud weight, lb/ft 3 psi/ft = mud weight, lb/ft 3 x Example: 100 lb/ft 3 fluid psi/ft = 100 lb/ft 3 x psi/ft = OR psi/ft = mud weight, lb/ft Example: 100 lb/ft 3 fluid psi/ft = 100 lb/ft psi/ft = Pressure gradient, psi/ft, using mud weight, specific gravity (SG) psi/ft = mud weight, SG x Example: 1.0 SG fluid psi/ft = 1.0 SG x psi/ft = Convert pressure gradient, psi/ft, to mud weight, ppg ppg = pressure gradient, psi/ft Example: psi/ft ppg = psi/ft : ppg = 9.6 Convert pressure gradient, psi/ft, to mud weight, lb/ft 3 lb/ft 3 = pressure gradient, psi/ft Example: psi/ft lb/ft 3 = psi/ft lb/ft 3 = 100 Convert pressure gradient, psi/ft, to mud weight, SG SG = pressure gradient, psi/ft Example: psi/ft SG psi/ft SG = Hydrostatic Pressure (HP) Hydrostatic pressure using ppg and feet as the units of measure 4

6 HP = mud weight, ppg x x true vertical depth (TVD), ft Example: mud weight = 13.5 ppg true vertical depth = 12,000 ft HP = 13.5 ppg x x 12,000 ft HP = 8424 psi Hydrostatic pressure, psi, using pressure gradient, psi/ft HP = psi/ft x true vertical depth, ft Example: Pressure gradient = psi/ft true vertical depth = 8500 ft HP = psi/ft x 8500 ft HP = 5304 psi Hydrostatic pressure, psi, using mud weight, lb/ft 3 HP = mud weight, lb/ft 3 x x TVD, ft Example: mud weight = 90 lb/ft 3 true vertical depth = 7500 ft HP = 90 lb/ft 3 x x 7500 ft HP = 4687 psi Hydrostatic pressure, psi, using meters as unit of depth HP = mud weight, ppg x x TVD, m x Example: Mud weight = 12.2 ppg true vertical depth = 3700 meters HP = 12.2 ppg x x 3700 x HP = 7,701 psi 3. Converting Pressure into Mud Weight Convert pressure, psi, into mud weight, ppg using feet as the unit of measure mud weight, ppg = pressure, psi TVD, ft Example: pressure = 2600 psi true vertical depth = 5000 ft mud, ppg = 2600 psi ft mud = 10.0 ppg Convert pressure, psi, into mud weight, ppg using meters as the unit of measure mud weight, ppg = pressure, psi TVD, m

7 Example: pressure = 3583 psi true vertical depth = 2000 meters mud wt, ppg = 3583 psi m mud wt = 10.5 ppg 4. Specific Gravity (SG) Specific gravity using mud weight, ppg SG = mud weight, ppg Example: ppg fluid SG = 15.0 ppg 8.33 SG = 1.8 Specific gravity using pressure gradient, psi/ft SG = pressure gradient, psi/ft Example: pressure gradient = psi/ft SG = psi/ft SG = 1.44 Specific gravity using mud weight, lb/ft 3 SG = mud weight, lb/ft Example: Mud weight = 120 lb/ft 3 SG = 120 lb/ft SG = 1.92 Convert specific gravity to mud weight, ppg mud weight, ppg = specific gravity x 8.33 Example: specific gravity = 1.80 mud wt, ppg = 1.80 x 8.33 mud wt = 15.0 ppg Convert specific gravity to pressure gradient, psi/ft psi/ft = specific gravity x Example: specific gravity = 1.44 psi/ft = 1.44 x psi/ft = Convert specific gravity to mud weight, lb/ft 3 lb/ft 3 = specific gravity x 62.4 Example: specific gravity =

8 lb/ft 3 = 1.92 x 62.4 lb/ft 3 = Equivalent Circulating Density (ECD), ppg ECD, ppg = (annular pressure, loss, psi ) TVD, ft + (mud weight, in use, ppg) Example: annular pressure loss = 200 psi true vertical depth = 10,000 ft ECD, ppg = 200 psi ,000 ft ppg ECD = 10.0 ppg 6. Maximum Allowable Mud Weight from Leak-off Test Data ppg = (Leak-off Pressure, psi ) (Casing Shoe TVD, ft) + (mud weight, ppg) Example: leak-off test pressure = 1140 psi casing shoe TVD = 4000 ft Mud weight = 10.0 ppg ppg = 1140 psi ft ppg ppg = Pump Output (P0) Triplex Pump Formula 1 PO, bbl/stk = x (liner diameter, in.) 2 X (stroke length, in.) Example: Determine the pump output, bbl/stk, at 100% efficiency for a 7-in, by 12-in, triplex pump: 100% = x 72 x % = bbl/stk Adjust the pump output for 95% efficiency: Decimal equivalent = = % = bbl/stk x % = bbl/stk Formula 2 PO, gpm = [3 (7 2 x ) S] x SPM 7

9 where D = liner diameter, in. S = stroke length, in. SPM = strokes per minute Example: Determine the pump output, gpm, for a 7-in, by 12-in, triplex pump at 80 strokes per minute: PO, gpm = [3 (72 x ) 12] x 80 PO, gpm = x x 80 PO = gpm Duplex Pump Formula x (Liner Diameter, in.) 2 x (stroke length, in.) = bbl/stk x (Liner Diameter, in.) 2 x (stroke length, in.) = bbl/stk Pump 100% eff = bbl/stk Example: Determine the output, bbl/stk, of a 5-1/2 in, by 14-in, duplex pump at 100% efficiency. Rod diameter = 2.0 in.: x x 14 = bbl/stk x x 14 = bbl/stk pump output 100% eff = bbl/stk Adjust pump output for 85% efficiency: Decimal equivalent = = % = bbl/stk x % = bbl/stk Formula 2 PO, bbl/stk = x S [2(D) 2 d 2 ] where D = liner diameter, in. S = stroke length, in. SPM = strokes per minute Example: Determine the output, bbl/stk, of a 5-1/2-in, by 14-in, duplex pump 100% efficiency. Rod diameter 2.0 in.: 100% = x 14 x [2 (5.5) ] 100% = x 14 x % = bbl/stk Adjust pump output for 85% efficiency: 85% = bbl/stk x % = bbl/stk 8. Annular Velocity (AV) 8

10 Annular velocity (AV), ft/min Formula 1 AV = pump output, bbl/min annular capacity, bbl/ft Example: pump output = 12.6 bbl/min annular capacity = bbl/ft AV = 12.6 bbl/min bbl/ft AV = ft/mm Formula 2 AV, ft/mm = 24.5 x Q. Dh 2 Dp 2 where Q = circulation rate, gpm, Dh = inside diameter of casing or hole size, in. Dp = outside diameter of pipe, tubing or collars, in. Example: pump output = 530 gpm hole size = 12-1/4th. pipe OD = 4-1/2 in. AV = 24.5 x AV = 12, AV = 100 ft/mm Formula 3 AV, ft/min = PO, bbl/min x Dh 2 Dp 2 Example: pump output = 12.6 bbl/min hole size = 12-1/4 in. pipe OD = 4-1/2 in. AV = 12.6 bbl/min x AV = AV = ft/mm Annular velocity (AV), ft/sec AV, ft/sec =17.16 x PO, bbl/min Dh 2 Dp 2 Example: pump output = 12.6 bbl/min hole size = 12-1/4 in. pipe OD = 4-1/2 in. 9

11 AV = x 12.6 bbl/min AV = AV = ft/sec Pump output, gpm, required for a desired annular velocity, ft/mm Pump output, gpm = AV, ft/mm (Dh 2 DP 2 ) 24 5 where AV = desired annular velocity, ft/min Dh = inside diameter of casing or hole size, in. Dp = outside diameter of pipe, tubing or collars, in. Example: desired annular velocity = 120 ft/mm pipe OD = 4-1/2 in. hole size = 12-1/4 in PO = 120 ( ) 24.5 PO = 120 x PO = PO = gpm Strokes per minute (SPM) required for a given annular velocity SPM = annular velocity, ft/mm x annular capacity, bbl/ft pump output, bbl/stk Example. annular velocity = 120 ft/min annular capacity = bbl/ft Dh = 12-1/4 in. Dp = 4-1/2 in. pump output = bbl/stk SPM = 120 ft/mm x bbl/ft bbl/stk SPM = SPM = Capacity Formulas 10

12 Annular capacity between casing or hole and drill pipe, tubing, or casing a) Annular capacity, bbl/ft = Dh 2 Dp Example: Hole size (Dh) = 12-1/4 in. Drill pipe OD (Dp) = 5.0 in. Annular capacity, bbl/ft = Annular capacity = bbl/ft b) Annular capacity, ft/bbl = (Dh 2 Dp 2 ) Example: Hole size (Dh) = 12-1/4 in. Drill pipe OD (Dp) = 5.0 in. Annular capacity, ft/bbl = ( ) Annular capacity = 8.23 ft/bbl c) Annular capacity, gal/ft = Dh 2 Dp Example: Hole size (Dh) = 12-1/4 in. Drill pipe OD (Dp) = 5.0 in. Annular capacity, gal/ft = Annular capacity = 5.1 gal/ft d) Annular capacity, ft/gal = (Dh 2 Dp 2 ) Example: Hole size (Dh) = 12-1/4 in. Drill pipe OD (Dp) = 5.0 in. Annular capacity, ft/gal = ( ) Annular capacity, ft/gal = ft/gal e) Annular capacity, ft 3 /Iinft Dh 2 Dp 2 11

13 Example: Hole size (Dh) = 12-1/4 in. Drill pipe OD (Dp) = 5.0 in. Annular capacity, ft 3 /linft = Annular capacity = ft 3 /linft f) Annular capacity, linft/ft 3 = (Dh 2 Dp 2 ) Example: Hole size (Dh) = 12-1/4 in. Drill pipe OD (Dp) = 5.0 in. Annular capacity, linft/ft 3 = ( ) Annular capacity = linft/ft 3 Annular capacity between casing and multiple strings of tubing a) Annular capacity between casing and multiple strings of tubing, bbl/ft: Annular capacity, bbl/ft = Dh 2 [(T 1 ) 2 + (T 2 ) 2 ] Example: Using two strings of tubing of same size: Dh = casing 7.0 in. 29 lb/ft ID = in. T 1 = tubing No /8 in. OD = in. T 2 = tubing No /8 in. OD = in. Annular capacity, bbl/ft = ( ) Annular capacity, bbl/ft = Annular capacity = bbl/ft b) Annular capacity between casing and multiple strings of tubing, ft/bbl: Annular capacity, ft/bbl = Dh 2 [(T 1 ) 2 + (T 2 ) 2 ] Example: Using two strings of tubing of same size: Dh = casing 7.0 in. 29 lb/ft ID = in. T 1 = tubing No /8 in. OD = in. T 2 = tubing No /8 in. OD = in. Annular capacity ft/bbl =

14 ( ) Annular capacity, ft/bbl = Annular capacity = ft/bbl c) Annular capacity between casing and multiple strings of tubing, gal/ft: Annular capacity, gal/ft = Dh 2 [(T~) 2 +(T 2 ) 2 ] Example: Using two tubing strings of different size: Dh = casing 7.0 in. 29 lb/ft ID = in. T 1 = tubing No /8 in. OD = in. T 2 = tubing No /2 in. OD = 3.5 in. Annular capacity, gal/ft = ( ) Annular capacity, gal/ft = Annular capacity = gal/ft d) Annular capacity between casing and multiple strings of tubing, ft/gal: Annular capacity, ft/gal = Dh 2 [(T 1 ) 2 + (T 2 ) 2 ] Example: Using two tubing strings of different sizes: Dh = casing 7.0 in. 29 lb/ft ID = in. T 1 = tubing No. I 2-3/8 in. OD = in. T 2 = tubing No /2 in. OD = 3.5 in. Annular capacity, ft/gal = ( ) Annular capacity, ft/gal = Annular capacity = ft/gal e) Annular capacity between casing and multiple strings of tubing, ft 3 /linft: Annular capacity, ft 3 /linft = Dh 2 [(T 1 ) 2 + (T 2 ) 2 + (T 3 ) 2 ]

15 Example: Using three strings of tubing: Dh = casing 9-5/8 in. 47 lb/ft ID = in. T 1 = tubing No /2 in. OD = 3.5 in. T 2 = tubing No /2 in. OD = 3.5 in. T 3 = tubing No /2 in. OD = 3.5 in. Annular capacity = ( ) Annular capacity, ft 3 /linft = Annular capacity = ft 3 /linft f) Annular capacity between casing and multiple strings of tubing, linft/ft 3 : Annular capacity, linft/ft 3 = Dh 2 [(T 1 ) 2 + (T 2 ) 2 + (T 3 ) 2 ] Example: Using three strings tubing of same size: Dh = casing 9-5/8 in. 47 lb/ft ID = in. T 1 = tubing No /2 in. OD = 3.5 in. T 2 = tubing No /2 in. OD = 3.5 in. T 3 = tubing No /2 in. OD = 3.5 in. Annular capacity = ( ) Annular capacity, linft/ft 3 = Annular capacity = linft/ft 3 Capacity of tubulars and open hole: drill pipe, drill collars, tubing, casing, hole, and any cylindrical object a) Capacity, bbl/ft = ID in. 2 Example: Determine the capacity, bbl/ft, of a 12-1/4 in. hole: Capacity, bbl/ft = Capacity = bbl/ft b) Capacity, ft/bbl = Example: Determine the capacity, ft/bbl, of 12-1/4 in. hole: Dh 2 Capacity, ft/bbl = Capacity = ft/bbl 14

16 c) Capacity, gal/ft = ID in. 2 Example: Determine the capacity, gal/ft, of 8-1/2 in. hole: Capacity, gal/ft = Capacity = gal/ft d) Capacity, ft/gal ID in 2 Example: Determine the capacity, ft/gal, of 8-1/2 in. hole: Capacity, ft/gal = Capacity = ft/gal e) Capacity, ft 3 /linft = ID 2 Example: Determine the capacity, ft 3 /linft, for a 6.0 in. hole: Capacity, ft 3 /Iinft = Capacity = ft 3 /linft f) Capacity, linftlft 3 = Example: Determine the capacity, linft/ft 3, for a 6.0 in. hole: ID, in. 2 Capacity, unit/ft 3 = Capacity = linft/ft 3 Amount of cuttings drilled per foot of hole drilled a) BARRELS of cuttings drilled per foot of hole drilled: Barrels = Dh 2 (1 % porosity) Example: Determine the number of barrels of cuttings drilled for one foot of 12-1/4 in. -hole drilled with 20% (0.20) porosity: Barrels = (1 0.20) Barrels = x 0.80 Barrels = b) CUBIC FEET of cuttings drilled per foot of hole drilled: Cubic feet = Dh 2 x (1 % porosity) 15

17 144 Example: Determine the cubic feet of cuttings drilled for one foot of 12-1/4 in. hole with 20% (0.20) porosity: Cubic feet = x (1 0.20) 144 Cubic feet = x x c) Total solids generated: Wcg = 35O Ch x L (l P) SG where Wcg = solids generated, pounds L = footage drilled, ft P = porosity, % Ch = capacity of hole, bbl/ft SG = specific gravity of cuttings Example: Determine the total pounds of solids generated in drilling 100 ft of a 12-1/4 in. hole ( bbl/ft). Specific gravity of cuttings = 2.40 gm/cc. Porosity = 20%: Wcg = 350 x x 100 (1 0.20) x 2.4 Wcg = pounds 10. Control Drilling Maximum drilling rate (MDR), ft/hr, when drifting large diameter holes (14-3/4 in. and larger) MDR, ft/hr = 67 x (mud wt out, ppg mud wt in, ppg) x (circulation rate, gpm) Dh 2 Example: Determine the MDR, ft/hr, necessary to keep the mud weight coming out at 9.7 ppg at the flow line: Data: Mud weight in = 9.0 ppg Circulation rate = 530 gpm Hole size = 17-1/2 in. MDR, ft/hr = 67 ( ) MDR, ft/hr = 67 x 0.7 x MDR, ft/hr = 24, MDR = ft/hr 16

18 11. Buoyancy Factor (BF) Buoyancy factor using mud weight, ppg BF = 65.5 mud weight, ppg 65.5 Example: Determine the buoyancy factor for a 15.0 ppg fluid: BF = BF = Buoyancy factor using mud weight, lb/ft 3 BF = 489 mud weight, lb/ft Example: Determine the buoyancy factor for a 120 lb/ft 3 fluid: BF = BF = Hydrostatic Pressure (HP) Decrease When POOH When pulling DRY pipe Step 1 Barrels = number of X average length X pipe displacement stands pulled per stand, ft displaced bbl/ft Step 2 HP psi decrease = barrels displaced x x mud weight, ppg (casing capacity pipe displacement) bbl/ft bbl/ft Example: Determine the hydrostatic pressure decrease when pulling DRY pipe out of the hole: Number of stands pulled = 5 Pipe displacement = bbl/ft Average length per stand = 92 ft Casing capacity = bbl/ft Mud weight = 11.5 ppg 17

19 Step 1 Barrels displaced = 5 stands x 92 ft/std x bbl/ft displaced Barrels displaced = 3.45 Step 2 HP, psi decrease = 3.45 barrels x x 11.5 ppg ( bbl/ft bbl/ft ) HP, psi decrease = 3.45 barrels x x 11.5 ppg HP decrease = psi When pulling WET pipe Step 1 Barrels displaced = number of stands pulled X average length X (pipe disp., bbl/ft + pipe cap., bbl/ft) per stand, ft Step 2 HP, psi = barrels displaced x x mud weight, ppg (casing capacity) (Pipe disp., + pipe cap.,) bbl/ft bbl/ft bbl/ft Example: Determine the hydrostatic pressure decrease when pulling WET pipe out of the hole: Number of stands pulled = 5 Pipe displacement = bbl/ft Average length per stand = 92 ft Pipe capacity = bbl/ft Mud weight = 11.5 ppg Casing capacity = bbl/ft Step 1 Barrels displaced = 5 stands x 92 ft/std x (.0075 bbl/ft bbl/ft) Barrels displaced = Step 2 HP, psi decrease = barrels x x 11.5 ppg ( bbl/ft) ( bbl/ft bbl/ft) HP, psi decrease = x x 11.5 ppg

20 HP decrease = psi 13. Loss of Overbalance Due to Falling Mud Level Feet of pipe pulled DRY to lose overbalance Feet = overbalance, psi (casing cap. pipe disp., bbl/ft) mud wt., ppg x x pipe disp., bbl/ft Example: Determine the FEET of DRY pipe that must be pulled to lose the overbalance using the following data: Amount of overbalance = 150 psi Casing capacity = bbl/ft Pipe displacement = bbl/ft Mud weight = 11.5 ppg Ft = 150 psi ( ) 11.5 ppg x x Ft = Ft = 2334 Feet of pipe pulled WET to lose overbalance Feet = overbalance, psi x (casing cap. pipe cap. pipe disp.) mud wt., ppg x x (pipe cap. : pipe disp., bbl/ft) Example: Determine the feet of WET pipe that must be pulled to lose the overbalance using the following data: Amount of overbalance = 150 psi Casing capacity = bbl/ft Pipe capacity = bbl/ft Pipe displacement = bbl/ft Mud weight = 11.5 ppg Feet = 150 psi x ( bbl/ft) 11.5 ppg x ( bbl/ft) Feet = 150 psi x ppg x x Feet = Feet =

21 14. Formation Temperature (FT) FT, F = (ambient surface temperature, F) + (temp. increase F per ft of depth x TVD, ft) Example: If the temperature increase in a specific area is F/ft of depth and the ambient surface temperature is 70 F, determine the estimated formation temperature at a TVD of 15,000 ft: FT, F = 70 F + (0.012 F/ft x 15,000 ft) FT, F = 70 F F FT = 250 F (estimated formation temperature) 15. Hydraulic Horsepower (HHP) HHP= P x Q 714 where HHP = hydraulic horsepower Q = circulating rate, gpm P = circulating pressure, psi Example: circulating pressure = 2950 psi circulating rate = 520 gpm HHP= 2950 x HHP = 1,534, HHP = Drill Pipe/Drill Collar Calculations Capacities, bbl/ft, displacement, bbl/ft, and weight, lb/ft, can be calculated from the following formulas: Capacity, bbl/ft = ID, in Displacement, bbl/ft = OD, in. 2 ID, in Weight, lb/ft = displacement, bbl/ft x 2747 lb/bbl 20

22 Example: Determine the capacity, bbl/ft, displacement, bbl/ft, and weight, lb/ft, for the following: Drill collar OD = 8.0 in. Drill collar ID = 2-13/16 in. Convert 13/16 to decimal equivalent: 13 : 16 = a) Capacity, bbl/ft = Capacity = bbl/ft b) Displacement, bbl/ft = Displacement, bbl/ft = Displacement = bbl/ft c) Weight, lb/ft = bbl/ft x 2747 lb/bbl Weight = lb/ft Rule of thumb formulas Weight, lb/ft, for REGULAR DRILL COLLARS can be approximated by the following formula: Weight, lb/ft = (OD, in. 2 ID, in. 2 ) x 2.66 Example: Regular drill collars Drill collar OD = 8.0 in. Drill collar ID = 2-13/16 in. Decimal equivalent = in. Weight, lb/ft = ( ) x 2.66 Weight, lb/ft = x 2.66 Weight = lb/ft Weight, lb/ft, for SPIRAL DRILL COLLARS can be approximated by the following formula: Weight, lb/ft = (OD, in. 2 ID, in. 2 ) x 2.56 Example: Spiral drill collars Drill collar OD = 8.0 in. Drill collar ID = 2-13/16 in. Decimal equivalent = in. Weight, lb/ft = ( ) x 2.56 Weight, lb/ft = x

23 Weight = lb/ft 17. Pump Pressure/Pump Stroke Relationship (Also Called the Roughneck s Formula) Basic formula New circulating = present circulating X (new pump rate, spm : old pump rate, spm) 2 pressure, psi pressure, psi Example: Determine the new circulating pressure, psi using the following data: Present circulating pressure = 1800 psi Old pump rate = 60 spm New pump rate = 30 spm New circulating pressure, psi = 1800 psi x (30 spm : 60 spm) 2 New circulating pressure, psi = 1800 psi x 0.25 New circulating pressure = 450 psi Determination of exact factor in above equation The above formula is an approximation because the factor 2 is a rounded-off number. To determine the exact factor, obtain two pressure readings at different pump rates and use the following formula: Factor = log (pressure 1 : pressure 2) log (pump rate 1 : pump rate 2) Example: Pressure 1 = gpm Pressure 2 = 450 psi ~ 120 gpm Factor = log (2500 psi 450 psi) log (315 gpm 120 gpm) Factor = log ( ) log (2.625) Factor = Example: Same example as above but with correct factor: New circulating pressure, psi = 1800 psi x (30 spm 60 spm) New circulating pressure, psi = 1800 psi x New circulating pressure = 525 psi 22

24 18. Cost Per Foot C T = B + C R (t + T) F Example: Determine the drilling cost (CT), dollars per foot using the following data: Bit cost (B) = $2500 Rotating time (I) = 65 hours Rig cost (CR) = $900/hour Round trip time (T) = 6 hours (for depth - 10,000 ft) Footage per bit (F) = 1300 ft C T = (65 + 6) 1300 C T = 66, C T = $51.08 per foot 19. Temperature Conversion Formulas Convert temperature, Fahrenheit (F) to Centigrade or Celsius (C) C = ( F 32) 5 OR C = F 32 x Example: Convert 95 F to C: C = (95 32) 5 OR C = x C =35 C = 35 Convert temperature, Centigrade or Celsius (C) to Fahrenheit F = ( C x 9) OR F = 24 x Example: Convert 24 C to F: F = (24 x 9) OR F = 24 x F = 75.2 F = 75.2 Convert temperature, Centigrade, Celsius (C) to Kelvin (K) K = C Example: Convert 35 C to K: 23

25 K = K = Convert temperature, Fahrenheit (F) to Rankine (R) R = F Example: Convert 260 F to R: R = R = Rule of thumb formulas for temperature conversion a) Convert F to C: C = F 30 2 Example: Convert 95 F to C C = C = 32.5 b) Convert C to F: F = C + C + 30 Example: Convert 24 C to F F = F = 78 24

26 CHAPTER TWO BASIC CALCULATIONS 25

27 1. Volumes and Strokes Drill string volume, barrels Barrels = ID, in. 2 x pipe length , Annular volume, barrels Barrels = Dh, in. 2 Dp, in Strokes to displace: drill string, Kelly to shale shaker and Strokes annulus, and total circulation from Kelly to shale shaker. Strokes = barrels pump output, bbl/stk Example: Determine volumes and strokes for the following: Drill pipe 5.0 in lb/f Inside diameter = in. Length = 9400 ft Drill collars 8.0 in. OD Inside diameter = 3.0 in. Length = 600 ft Casing 13-3/8 in lb/f Inside diameter = in. Setting depth = 4500 ft Pump data 7 in. by 12 in. triplex Efficiency = 95% Pump output = 95% Hole size = 12-1/4 in. Drill string volume a) Drill pipe volume, bbl: Barrels = x 9400 ft Barrels = x 9400 ft Barrels = b) Drill collar volume, bbl: Barrels = x 600 ft Barrels = x 600 ft Barrels = 5.24 c) Total drill string volume: Total drill string vol., bbl = bbl bbl Total drill string vol. = bbl Annular volume a) Drill collar / open hole: Barrels = x 600 ft Barrels = x 600 ft Barrels =

28 b) Drill pipe / open hole: Barrels = x 4900 ft Barrels = x 4900 ft Barrels = c) Drill pipe / cased hole: Barrels = x 4500 ft Barrels = x 4500 ft Barrels = d) Total annular volume: Total annular vol. = Total annular vol. = barrels Strokes a) Surface to bit strokes: Strokes = drill string volume, bbl pump output, bbl/stk Surface to bit strokes = bbl bbl/stk Surface to bit strokes = 1266 b) Bit to surface (or bottoms-up strokes): Strokes = annular volume, bbl pump output, bbl/stk Bit to surface strokes = bbl bbl/stk Bit to surface strokes = 9058 c) Total strokes required to pump from the Kelly to the shale shaker: Strokes = drill string vol., bbl + annular vol., bbl pump output, bbl/stk Total strokes = ( ) Total strokes = Total strokes = 10, Slug Calculations Barrels of slug required for a desired length of dry pipe Step 1 Hydrostatic pressure required to give desired drop inside drill pipe: HP, psi = mud wt, ppg x x ft of dry pipe Step 2 Difference in pressure gradient between slug weight and mud weight: psi/ft = (slug wt, ppg mud wt, ppg) x

29 Step 3 Length of slug in drill pipe: Slug length, ft = pressure, psi difference in pressure gradient, psi/ft Step 4 Volume of slug, barrels: Slug vol., bbl = slug length, ft x drill pipe capacity, bbl/ft Example: Determine the barrels of slug required for the following: Desired length of dry pipe (2 stands) = 184 ft Drill pipe capacity 4-1/2 in lb/ft = bbl/ft Mud weight = 12.2 ppg Slug weight = 13.2 ppg Step 1 Hydrostatic pressure required: HP, psi = 12.2 ppg x x 184 ft HP = 117 psi Step 2 Difference in pressure gradient, psi/ft: psi/ft = (13.2 ppg 12.2 ppg) x psi/ft = Step 3 Length of slug in drill pipe, ft: Slug length, ft = 117 psi : Slug length = 2250 ft Step 4 Volume of slug, bbl: Slug vol., bbl = 2250 ft x bbl/ft Slug vol. = 32.0 bbl Weight of slug required for a desired length of dry pipe with a set volume of slug Step 1 Length of slug in drill pipe, ft: Slug length, ft = slug vol., bbl drill pipe capacity, bbl/ft Step 2 Hydrostatic pressure required to give desired drop inside drill pipe: HP, psi = mud wt, ppg x x ft of dry pipe Step 3 Weight of slug, ppg: Slug wt, ppg = HP, psi slug length, ft + mud wt, ppg Example: Determine the weight of slug required for the following: Desired length of dry pipe (2 stands) = 184 ft Mud weight = 12.2 ppg 28

30 Drill pipe capacity 4-1/2 in lb/ft = bbl/ft Volume of slug = 25 bbl Step 1 Length of slug in drill pipe, ft: Slug length, ft = 25 bbl ± bbl/ft Slug length = 1758 ft Step 2 Hydrostatic pressure required: HP, Psi = 12.2 ppg x x 184 ft HP, Psi = ll7psi Step 3 Weight of slug, ppg: Slug wt, ppg = 117 psi ft ppg Slug wt, ppg = 1.3 ppg ppg Slug wt = 13.5 ppg Volume, height, and pressure gained because of slug: a) Volume gained in mud pits after slug is pumped, due to U-tubing: Vol., bbl = ft of dry pipe x drill pipe capacity, bbl/ft b) Height, ft, that the slug would occupy in annulus: Height, ft = annulus vol., ft/bbl x slug vol., bbl c) Hydrostatic pressure gained in annulus because of slug: HP, psi = height of slug in annulus, ft X difference in gradient, psi/ft between slug wt and mud wt Example: Feet of dry pipe (2 stands) = 184 ft Slug volume = 32.4 bbl Slug weight = 13.2 ppg Mud weight = 12.2 ppg Drill pipe capacity 4-1/2 in lb/ft = bbl/ft Annulus volume (8-1/2 in. by 4-1/2 in.) = 19.8 ft/bbl a) Volume gained in mud pits after slug is pumped due to U-tubing: Vol., bbl = 184 ft x bbl/ft Vol. = 2.62 bbl b) Height, ft, that the slug would occupy in the annulus: Height, ft = 19.8 ft/bbl x 32.4 bbl Height = ft c) Hydrostatic pressure gained in annulus because of slug: HP, psi = ft ( ) x HP, psi = ft x HP = 33.4 psi 29

31 3. Accumulator Capacity Usable Volume Per Bottle Usable Volume Per Bottle NOTE: The following will be used as guidelines: Volume per bottle = 10 gal Pre-charge pressure = 1000 psi Maximum pressure = 3000 psi Minimum pressure remaining after activation = 1200 psi Pressure gradient of hydraulic fluid = psi/ft Boyle s Law for ideal gases will be adjusted and used as follows: P 1 V 1 = P 2 V 2 Surface Application Step 1 Determine hydraulic fluid necessary to increase pressure from pre-charge to minimum: P 1 V 1 = P 2 V psi x 10 gal = 1200 psi x V 2 10,000 = V V 2 = 8.33 The nitrogen has been compressed from 10.0 gal to 8.33 gal = 1.67 gal of hydraulic fluid per bottle. NOTE: This is dead hydraulic fluid. The pressure must not drop below this minimum value. Step 2 Determine hydraulic fluid necessary to increase pressure from pre-charge to maximum: P 1 V 1 = P 2 V psi x 10 gals = 3000 psi x V 2 10,000 = V V 2 = 3.33 The nitrogen has been compressed from 10 gal to 3.33 gal = 6.67 gal of hydraulic fluid per bottle. Step 3 Determine usable volume per bottle: Useable vol./bottle = Total hydraulic fluid/bottle Dead hydraulic fluid/bottle 30

32 Useable vol./bottle = Useable vol./bottle = 5.0 gallons Subsea Applications In subsea applications the hydrostatic pressure exerted by the hydraulic fluid must be compensated for in the calculations: Example: Same guidelines as in surface applications: Water depth = 1000 ft Hydrostatic pressure of hydraulic fluid = 445 psi Step 1 Adjust all pressures for the hydrostatic pressure of the hydraulic fluid: Pre-charge pressure = 1000 psi psi = 1445 psi Minimum pressure = 1200 psi psi = 1645 psi Maximum pressure = 3000 psi psi = 3445 psi Step 2 Determine hydraulic fluid necessary to increase pressure from pre-charge to minimum: P 1 V 1 = P 2 V 2 = 1445 psi x 10 = 1645 x V 2 14,450 = V V 2 = 8.78 gal = 1.22 gal of dead hydraulic fluid Step 3 Determine hydraulic fluid necessary to increase pressure from pre-charge to maximum: 1445 psi x 10 = 3445 psi x V = V V 2 = 4.19 gal = 5.81 gal of hydraulic fluid per bottle. Step 4 Determine useable fluid volume per bottle: Useable vol./bottle = Total hydraulic fluid/bottle Dead hydraulic fluid/bottle Useable vol./bottle = Useable vol./bottle = 4.59 gallons Accumulator Pre-charge Pressure 31

33 The following is a method of measuring the average accumulator pre-charge pressure by operating the unit with the charge pumps switched off: P,psi = vol. removed, bbl total acc. vol., bbl x ((Pf x Ps) (Ps Pf)) where P = average pre-charge pressure, psi Ps = starting accumulator pressure, psi Pf = final accumulator pressure, psi Example: Determine the average accumulator pre-charge pressure using the following data: Starting accumulator pressure (Ps) = 3000 psi Final accumulator pressure (Pf) = 2200 psi Volume of fluid removed = 20 gal Total accumulator volume = 180 gal P, psi = x ((2200 x 3000) ( )) P, psi = x (6,600, ) P, psi = x 8250 P = 9l7psi 4. Bulk Density of Cuttings (Using Mud Balance) Procedure: 1. Cuttings must be washed free of mud. In an oil mud, diesel oil can be used instead of water. 2. Set mud balance at 8.33 ppg. 3. Fill the mud balance with cuttings until a balance is obtained with the lid in place. 4. Remove lid, fill cup with water (cuttings included), replace lid, and dry outside of mud balance. 5. Move counterweight to obtain new balance. The specific gravity of the cuttings is calculated as follows: SG = 1. 2 (O.l2 x Rw) where SG = specific gravity of cuttings bulk density Rw = resulting weight with cuttings plus water, ppg Example: Rw = 13.8 ppg. Determine the bulk density of cuttings: SG= 1. 2 (0.12 x 13.8) SG = SG =

34 5. Drill String Design (Limitations) The following will be determined: Length of bottom hole assembly (BHA) necessary for a desired weight on bit (WOB). Feet of drill pipe that can be used with a specific bottom hole assembly (BHA). 1. Length of bottom hole assembly necessary for a desired weight on bit: Length, ft = WOB x f Wdc x BF where WOB = desired weight to be used while drilling f = safety factor to place neutral point in drill collars Wdc = drill collar weight, lb/ft BF = buoyancy factor Example: Desired WOB while drilling = 50,000 lb Safety factor = 15% Drill collar weight 8 in. OD 3 in. ID = 147 lb/ft Mud weight = 12.0 ppg Solution: a) Buoyancy factor (BF): BF = ppg 65.5 BF = b) Length of bottom hole assembly (BHA) necessary: Length, ft = x x Length, ft = 57, Length = 479 ft 2. Feet of drill pipe that can be used with a specific BHA NOTE: Obtain tensile strength for new pipe from cementing handbook or other source. a) Determine buoyancy factor: BF = 65.5 mud weight, ppg

35 b) Determine maximum length of drill pipe that can be run into the hole with a specific BHA.: Length max =[(T x f) MOP Wbha] x BF Wdp where T = tensile strength, lb for new pipe f = safety factor to correct new pipe to no. 2 pipe MOP = margin of overpull Wbha = BHA weight in air, lb/ft Wdp = drill pipe weight in air, lb/ft. including tool joint BF = buoyancy factor c) Determine total depth that can be reached with a specific bottom-hole assembly: Total depth, ft = length max + BHA length Example: Drill pipe (5.0 in.) = lb/ft - Grade G Tensile strength = 554,000 lb BHA weight in air = 50,000 lb BHA length = 500 ft Desired overpull = 100,000 lb Mud weight = 13.5 ppg Safety factor = 10% a) Buoyancy factor: BF = BF = b) Maximum length of drill pipe that can be run into the hole: Length max = [(554,000 x 0.90) 100,000 50,000] x Length max = Length max = 12,655 ft c) Total depth that can be reached with this BHA and this drill pipe: Total depth, ft = 12,655 ft ft Total depth = 13,155 ft 6. Ton-Mile (TM) Calculations All types of ton-mile service should be calculated and recorded in order to obtain a true picture of the total service received from the rotary drilling line. These include: 34

36 1. Round trip ton-miles 2. Drilling or connection ton-miles 3. Coring ton-miles 4. Ton-miles setting casing 5. Short-trip ton-miles Round trip ton-miles (RT TM ) RT TM = Wp x D x (Lp + D) (2 x D) (2 x Wb + Wc) 5280 x 2000 where RT TM = round trip ton-miles Wp = buoyed weight of drill pipe, lb/ft D = depth of hole, ft Lp = length of one stand of drill pipe, (aye), ft Wb = weight of travelling block assembly, lb Wc = buoyed weight of drill collars in mud minus the buoyed weight of the same length of drill pipe, lb 2000 = number of pounds in one ton 5280 = number of feet in one mile Example: Round trip ton-miles Mud weight = 9.6 ppg Average length of one stand = 60 ft (double) Drill pipe weight = 13.3 lb/ft Measured depth = 4000 ft Drill collar length = 300 ft Travelling block assembly = 15,000 lb Drill collar weight = 83 lb/ft Solution: a) Buoyancy factor: BF = ppg. : 65.5 BF = b) Buoyed weight of drill pipe in mud, lb/ft (Wp): Wp = 13.3 lb/ft x Wp = lb/ft c) Buoyed weight of drill collars in mud minus the buoyed weight of the same length of drill pipe, lb (Wc): Wc = (300 x 83 x ) (300 x 13.3 x ) Wc = 21,250 3,405 Wc = 17,845 lb Round trip ton-miles = x 4000 x ( ) + (2 x 4000) x (2 x ) 5280 x 2000 RT TM = x 4000 x x (30, ,845) 5280 x 2000 RT TM = x 4000 x x 47,845 35

37 10,560,000 RT TM = ,560,000 RT TM = 53.7 Drilling or connection ton-miles The ton-miles of work performed in drilling operations is expressed in terms of work performed in making round trips. These are the actual ton-miles of work in drilling down the length of a section of drill pipe (usually approximately 30 ft) plus picking up, connecting, and starting to drill with the next section. To determine connection or drilling ton-miles, take 3 times (ton-miles for current round trip minus ton-miles for previous round trip): Td = 3(T 2 T 1 ) where Td = drilling or connection ton-miles T 2 = ton-miles for one round trip depth where drilling stopped before coming out of hole. T 1 = ton-miles for one round trip depth where drilling started. Example: Ton-miles for 4600 ft = 64.6 Ton-miles for 4000 ft = 53.7 Td = 3 x ( ) Td = 3 x 10.9 Td = 32.7 ton-miles Ton-miles during coring operations The ton-miles of work performed in coring operations, as for drilling operations, is expressed in terms of work performed in making round trips. To determine ton-miles while coring, take 2 times ton-miles for one round trip at the depth where coring stopped minus ton-miles for one round trip at the depth where coring began: Tc = 2 (T 4 T 3 ) where Tc = ton-miles while coring T 4 = ton-miles for one round trip depth where coring stopped before coming out of hole T 3 = ton-miles for one round trip depth where coring started after going in hole Ton-miles setting casing The calculations of the ton-miles for the operation of setting casing should be determined as for drill pipe, but with the buoyed weight of the casing being used, and with the result being 36

38 multiplied by one-half, because setting casing is a one-way (1/2 round trip) operation. Tonmiles for setting casing can be determined from the following formula: Tc = Wp x D x (Lcs + D) + D x Wb x x 2000 where Tc = ton-miles setting casing Lcs = length of one joint of casing, ft Ton-miles while making short trip Wp = buoyed weight of casing, lb/ft Wb = weight of travelling block assembly, lb The ton-miles of work performed in short trip operations, as for drilling and coring operations, is also expressed in terms of round trips. Analysis shows that the ton-miles of work done in making a short trip is equal to the difference in round trip ton-miles for the two depths in question. Tst = T 6 T 5 where Tst = ton-miles for short trip T 6 = ton-miles for one round trip at the deeper depth, the depth of the bit before starting the short trip. T 5 = ton-miles for one round trip at the shallower depth, the depth that the bit is pulled up to. 7. Cementing Calculations Cement additive calculations a) Weight of additive per sack of cement: Weight, lb = percent of additive x 94 lb/sk b) Total water requirement, gal/sk, of cement: Water, gal/sk = Cement water requirement, gal/sk + Additive water requirement, gal/sk c) Volume of slurry, gal/sk: Vol gal/sk = 94 lb + weight of additive, lb + water volume, gal SG of cement x 8.33 lb/gal SG of additive x 8.33 lb/gal d) Slurry yield, ft 3 /sk: Yield, ft 3 /sk = vol. of slurry, gal/sk 7.48 gal/ft 3 e) Slurry density, lb/gal: Density, lb/gal = 94 + wt of additive + (8.33 x vol. of water/sk) vol. of slurry, gal/sk 37

39 Example: Class A cement plus 4% bentonite using normal mixing water: Determine the following: Amount of bentonite to add Total water requirements Slurry yield Slurry weight 1) Weight of additive: Weight, lb/sk = 0.04 x 94 lb/sk Weight = 3.76 lb/sk 2) Total water requirement: Water = 5.1 (cement) (bentonite) Water = 7.7 gal/sk of cement 3) Volume of slurry: Vol, gal/sk = x x 8.33 Vol. gallsk = Vol. = gal/sk 4) Slurry yield, ft 3 /sk: Yield, ft 3 /sk = gal/sk : 7.48 gal/ft 3 Yield = 1.53 ft 3 /sk 5) Slurry density, lb/gal: Density, lb/gal = (8.33 x 7.7) Density, lb/gal = Density = lb/gal Water requirements a) Weight of materials, lb/sk: Weight, lb/sk = 94 + (8.33 x vol of water, gal) + (% of additive x 94) b) Volume of slurry, gal/sk: Vol, gal/sk = 94 lb/sk + wt of additive, lb/sk + water vol, gal SG x 8.33 SG x

40 c) Water requirement using material balance equation: D 1 V 1 = D 2 V 2 Example: Class H cement plus 6% bentonite to be mixed at 14.0 lb/gal. Specific gravity of bentonite = Determine the following: Bentonite requirement, lb/sk Water requirement, gallsk Slurry yield, ft 3 /sk Check slurry weight, lb/gal 1) Weight of materials, lb/sk: Weight, lb/sk = 94 + (0.06 x 94) + (8.33 x y ) Weight, lb/sk = y Weight = y 2) Volume of slurry, gal/sk: Vol, gal/sk = y 3.14 x x 8.33 Vol, gal/sk = y Vol, gal/sk = ) Water requirements using material balance equation y = ( y ) x y = y = 14.0 y y 45.6 = 5.67 y 45.6 : 5.67 = y 8.0 = y Thus, water required = 8.0 gal/sk of cement 4) Slurry yield, ft 3 /sk: Yield, ft3/sk = Yield, ft 3 /sk = Yield = 1.59 ft 3 /sk 5) Check slurry density, lb/gal: Density, lb/gal = (8.33 x 8.0) Density, lb/gal = Density = 14.0 lb/gal 39

41 Field cement additive calculations When bentonite is to be pre-hydrated, the amount of bentonite added is calculated based on the total amount of mixing water used. Cement program: 240 sk cement; slurry density = 13.8 ppg; 8.6 gal/sk mixing water; 1.5% bentonite to be pre-hydrated: a) Volume of mixing water, gal: Volume = 240 sk x 8.6 gal/sk Volume = 2064 gal b) Total weight, lb, of mixing water: Weight = 2064 gal x 8.33 lb/gal Weight = 17,193 lb c) Bentonite requirement, Lb: Bentonite = 17,193 lb x 0.015% Bentonite = lb Other additives are calculated based on the weight of the cement: Cement program: 240 sk cement; 0.5% Halad; 0.40% CFR-2: a) Weight of cement: Weight = 240 sk x 94 lb/sk Weight = 22,560 lb b) Halad = 0.5% Halad = 22,560 lb x Halad = lb c) CFR-2 = 0.40% CFR-2 = 22,560 lb x CFR-2 = lb Table 2-1 Water Requirements and Specific Gravity of Common Cement Additives Water Requirement ga1/94 lb/sk Specific Gravity API Class Cement Class A & B

42 Class C Class D & E Class G Class H Chem Comp Cement Attapulgite 1.3/2% in cement 2.89 Cement Fondu Table 2-1 (continued) Water Requirements and Specific Gravity of Common Cement Additives Water Requirement ga1/94 lb/sk Lumnite Cement Trinity Lite-weight Cement Bentonite 1.3/2% in cement 2.65 Calcium Carbonate Powder Calcium Chloride Cal-Seal (Gypsum Cement) CFR-l CFR D-Air D-Air Diacel A Diacel D /10% in cement 2.10 Diacel LWL 0 (up to 0.7%) 0.8:1/1% in cement 1.36 Gilsonite 2/50-lb/ft Halad-9 0(up to 5%) over 5% 1.22 Halad HR HR HR HR HR Hydrated Lime Hydromite Iron Carbonate LA-2 Latex NF-D Perlite regular 4/8 lb/ft Perlite 6 6/38 lb/ft 3 Pozmix A Salt (NaCI) Specific Gravity 41

43 Sand Ottawa Silica flour 1.6/35% in cement 2.63 Coarse silica Spacer sperse Spacer mix (liquid) Tuf Additive No Tuf Additive No Tuf Plug Weighted Cement Calculations Amount of high density additive required per sack of cement to achieve a required cement slurry density x = (Wt x SGc) + (wt x CW) (8.33 x CW) (1+ (AW 100)) - (wt (SGa x 8.33)) - (wt + (AW 100)) where x = additive required, pounds per sack of cement Wt = required slurry density, lb/gal SGc = specific gravity of cement CW = water requirement of cement AW = water requirement of additive SGa = specific gravity of additive Additive Water Requirement ga1/94 lb/sk Specific Gravity Hematite Ilmenite Barite Sand API Cements Class A & B Class C Class D,E,F,H Class G Example: Determine how much hematite, lb/sk of cement, would be required to increase the density of Class H cement to 17.5 lb/gal: Water requirement of cement = 4.3 gal/sk Water requirement of additive (hematite) = 0.34 gal/sk Specific gravity of cement = 3.14 Specific gravity of additive (hematite) = 5.02 Solution: x = (17.5 x ) + (17.5 x 4.3) 94 (8.33 x 4.3) (1+ ( )) (17.5 (5.02 x 8.33)) x (17.5 x ( )) x =

44 x = x = 15.1 lb of hematite per sk of cement used 9. Calculations for the Number of Sacks of Cement Required If the number of feet to be cemented is known, use the following: Step 1 : Determine the following capacities: a) Annular capacity, ft 3 /ft: Annular capacity, ft 3 /ft = Dh, in. 2 Dp, in. 2 b) Casing capacity, ft 3 /ft: Casing capacity, ft 3 /ft = ID, in. 2 c) Casing capacity, bbl/ft: Casing capacity, bbl/ft = ID, in Step 2 : Determine the number of sacks of LEAD or FILLER cement required: Sacks required = feet to be x Annular capacity, x excess : yield, ft 3 /sk LEAD cement cemented ft 3 /ft Step 3 : Determine the number of sacks of TAIL or NEAT cement required Sacks required annulus = feet to be x annular capacity, ft 3 /ft x excess : yield, ft 3 /sk cemented TAIL cement Sacks required casing = no. of feet x annular capacity, x excess : yield, ft 3 /sk between float ft 3 /ft TAIL cement collar & shoe Total Sacks of TAIL cement required: Sacks = sacks required in annulus + sacks required in casing Step 4 Determine the casing capacity down to the float collar: 43

45 Casing capacity, bbl = casing capacity, bbl/ft x feet of casing to the float collar Step 5 Determine the number of strokes required to bump the plug: Strokes = casing capacity, bbl : pump output, bbl/stk Example: From the data listed below determine the following: 1. How many sacks of LEAD cement will be required? 2. How many sacks of TAIL cement will be required? 3. How many barrels of mud will be required to bump the plug? 4. How many strokes will be required to bump the top plug? Data: Casing setting depth = 3000 ft Hole size = 17-1/2 in. Casing 54.5 lb/ft = 13-3/8 in. Casing ID = in. Float collar (feet above shoe) = 44 ft Pump (5-1/2 in. by 14 in. 90% eff) bbl/stk Cement program: LEAD cement (13.8 lb/gal) = 2000 ft TAIL cement (15.8 lb/gal) = 1000 ft Excess volume = 50% slurry yield = 1.59 ft 3 /sk slurry yield = 1.15 ft 3 /sk Step 1 Determine the following capacities: a) Annular capacity, ft 3 /ft: Annular capacity, ft 3 /ft = Annular capacity, ft 3 /ft = Annular capacity = ft 3 /ft b) Casing capacity, ft 3 /ft: Casing capacity, ft 3 /ft = Casing capacity, ft 3 /ft = Casing capacity = ft 3 /ft c) Casing capacity, bbl/ft: Casing capacity, bbl/ft = Casing capacity, bbl/ft =

46 Casing capacity = bbl/ft Step 2 Determine the number of sacks of LEAD or FILLER cement required: Sacks required = 2000 ft x ft 3 /ft x ft 3 /sk Sacks required = 1311 Step 3 Determine the number of sacks of TAIL or NEAT cement required: Sacks required annulus = 1000 ft x ft 3 /ft x ft 3 /sk Sacks required annulus = 906 Sacks required casing = 44 ft x ft 3 /ft 1.15 ft 3 /sk Sacks required casing = 33 Total sacks of TAIL cement required: Sacks = Sacks = 939 Step 4 Determine the barrels of mud required to bump the top plug: Casing capacity, bbl = (3000 ft 44 ft) x bbl/ft Casing capacity = bbl Step 5 Determine the number of strokes required to bump the top plug: Strokes = bbl bbl/stk Strokes = Calculations for the Number of Feet to Be Cemented If the number of sacks of cement is known, use the following: Step 1 Determine the following capacities: a) Annular capacity, ft 3 /ft: Annular capacity, ft 3 /ft = Dh, in. 2 Dp, in , 35 b) Casing capacity, ft 3 /ft: Casing capacity, ft 3 /ft = ID, in Step 2 Determine the slurry volume, ft 3 Slurry vol, ft 3 = number of sacks of cement to be used x slurry yield, ft 3 /sk 45

47 Step 3 Determine the amount of cement, ft 3, to be left in casing: Cement in = (feet of setting depth of ) x (casing capacity, ft 3 /ft) : excess casing, ft 3 (casing cementing tool, ft) Step 4 Determine the height of cement in the annulus feet of cement: Feet = (slurry vol, ft 3 cement remaining in casing, ft 3 ) + (annular capacity, ft 3 /ft) excess Step 5 Determine the depth of the top of the cement in the annulus: Depth ft = casing setting depth, ft ft of cement in annulus Step 6 Determine the number of barrels of mud required to displace the cement: Barrels = feet drill pipe x drill pipe capacity, bbl/ft Step 7 Determine the number of strokes required to displace the cement: Strokes = bbl required to displace cement : pump output, bbl/stk Example: From the data listed below, determine the following: 1. Height, ft, of the cement in the annulus 2. Amount, ft 3, of the cement in the casing 3. Depth, ft, of the top of the cement in the annulus 4. Number of barrels of mud required to displace the cement 5. Number of strokes required to displace the cement Data: Casing setting depth = 3000 ft Hole size = 17-1/2 in. Casing 54.5 lb/ft = 13-3/8 in. Casing ID = in. Drill pipe (5.0 in lb/ft) = bbl/ft Pump (7 in. by 12 in. 95% eff.) = bbl/stk Cementing tool (number of feet above shoe) = 100 ft Cementing program: NEAT cement = 500 sk Slurry yield = 1.15 ft 3 /sk Excess volume = 50% Step 1 Determine the following capacities: a) Annular capacity between casing and hole, ft 3 /ft: Annular capacity, ft 3 /ft = Annular capacity, ft 3 /ft = Annular capacity = ft 3 /ft 46

48 b) Casing capacity, ft 3 /ft: Casing capacity, ft 3 /ft = Casing capacity, ft 3 /ft = Casing capacity = ft 3 /ft Step 2 Determine the slurry volume, ft 3 : Slurry vol, ft 3 = 500 sk x 1.15 ft 3 /sk Slurry vol = 575 ft 3 Step 3 Determine the amount of cement, ft 3, to be left in the casing: Cement in casing, ft 3 = (3000 ft 2900 ft) x ft 3 /ft Cement in casing, ft 3 = ft 3 Step 4 Determine the height of the cement in the annulus feet of cement: Feet = (575 ft ft 3 ) ft 3 /ft 1.50 Feet = Step 5 Determine the depth of the top of the cement in the annulus: Depth = 3000 ft ft Depth = ft Step 6 Determine the number of barrels of mud required to displace the cement: Barrels = 2900 ft x bbl/ft Barrels = 51.5 Step 7 Determine the number of strokes required to displace the cement: Strokes = 51.5 bbl bbl/stk Strokes = Setting a Balanced Cement Plug 47

49 Step 1 Determine the following capacities: a) Annular capacity, ft 3 /ft, between pipe or tubing and hole or casing: Annular capacity, ft 3 /ft = Dh in. 2 Dp in b) Annular capacity, ft/bbl between pipe or tubing and hole or casing: Annular capacity, ft/bbl = Dh, in. 2 Dp, in. 2 c) Hole or casing capacity, ft 3 /ft: Hole or capacity, ft 3 /ft = ID in d) Drill pipe or tubing capacity, ft 3 /ft: Drill pipe or tubing capacity, ft 3 /ft = ID in. 2 e) Drill pipe or tubing capacity, bbl/ft: Drill pipe or tubing capacity, bbl/ft = ID in Step 2 Determine the number of SACKS of cement required for a given length of plug, OR determine the FEET of plug for a given number of sacks of cement: a) Determine the number of SACKS of cement required for a given length of plug: Sacks of = plug length, ft x hole or casing capacity ft 3 /ft, x excess slurry yield, ft 3 /sk cement NOTE: If no excess is to be used, simply omit the excess step. OR b) Determine the number of FEET of plug for a given number of sacks of cement: Feet = sacks of cement x slurry yield, ft 3 /sk hole or casing capacity, ft 3 /ft excess NOTE: If no excess is to be used, simply omit the excess step. Step 3 Determine the spacer volume (usually water), bbl, to be pumped behind the slurry to balance the plug: Spacer vol, bbl capacity, = annular capacity, excess x spacer vol ahead, x pipe or tubing ft/bbl bbl bbl/ft 48

50 NOTE: If no excess is to be used, simply omit the excess step. Step 4 Determine the plug length, ft, before the pipe is withdrawn: Plug length, ft = sacks of x slurry yield, annular capacity, x excess + pipe or tubing cement ft 3 /sk ft 3 /ft capacity, ft 3 /ft NOTE: If no excess is to be used, simply omit the excess step. Step 5 Determine the fluid volume, bbl, required to spot the plug: Vol, bbl = length of pipe plug length, ft x pipe or tubing spacer vol behind or tubing, ft capacity, bbl/ft slurry, bbl Example 1: A 300 ft plug is to be placed at a depth of 5000 ft. The open hole size is 8-1/2 in. and the drill pipe is 3-1/2 in lb/ft; ID in. Ten barrels of water are to be pumped ahead of the slurry. Use a slurry yield of 1.15 ft 3 /sk. Use 25% as excess slurry volume: Determine the following: 1. Number of sacks of cement required 2. Volume of water to be pumped behind the slurry to balance the plug 3. Plug length before the pipe is withdrawn 4. Amount of mud required to spot the plug plus the spacer behind the plug Step 1 Determined the following capacities: a) Annular capacity between drill pipe and hole, ft 3 /ft: Annular capacity, ft 3 /ft = Annular capacity = ft 3 /ft b) Annular capacity between drill pipe and hole, ft/bbl: Annular capacity, ft/bbl = Annular capacity = ft/bbl c) Hole capacity, ft 3 /ft: Hole capacity, ft 3 /ft = Hole capacity = ft 3 /ft d) Drill pipe capacity, bbl/ft: 49

51 Drill pipe capacity, bbl/ft = Drill pipe capacity = bbl/ft e) Drill pipe capacity, ft 3 /ft: Drill pipe capacity, ft 3 /ft = Drill pipe capacity = ft 3 /ft Step 2 Determine the number of sacks of cement required: Sacks of cement = 300 ft x ft 3 /ft x ft 3 /sk Sacks of cement = 129 Step 3 Determine the spacer volume (water), bbl, to be pumped behind the slurry to balance the plug: Spacer vol, bbl = ft/bbl 1.25 x 10 bbl x bbl/ft Spacer vol = bbl Step 4 Determine the plug length, ft, before the pipe is withdrawn: Plug length, ft = (129 sk x 1.15 ft3/sk) ( ft 3 /ft x ft 3 /ft) Plug length, ft = ft ft 3 /ft Plug length = 329 ft Step 5 Determine the fluid volume, bbl, required to spot the plug: Vol, bbl = [(5000 ft 329 ft) x bbl/ft] 1.0 bbl Vol, bbl = bbl 1.0 bbl Volume = 33.6 bbl Example 2: Determine the number of FEET of plug for a given number of SACKS of cement: A cement plug with 100 sk of cement is to be used in an 8-1/2 in, hole. Use 1.15 ft 3 /sk for the cement slurry yield. The capacity of 8-1/2 in. hole = ft 3 /ft. Use 50% as excess slurry volume: Feet = 100 sk x 1.15 ft 3 /sk ft 3 /ft 1.50 Feet = Differential Hydrostatic Pressure Between Cement in the Annulus and Mud Inside the Casing 1. Determine the hydrostatic pressure exerted by the cement and any mud remaining in the 50

52 annulus. 2. Determine the hydrostatic pressure exerted by the mud and cement remaining in the casing. 3. Determine the differential pressure. Example: 9-5/8 in. casing 43.5 lb/ft in 12-1/4 in. hole: Well depth = 8000 ft Cementing program: LEAD slurry 2000 ft = 13.8 lb/gal TAIL slurry 1000 ft = 15.8 lb/gal Mud weight = 10.0 lb/gal Float collar (No. of feet above shoe) = 44 ft Determine the total hydrostatic pressure of cement and mud in the annulus a) Hydrostatic pressure of mud in annulus: HP, psi = 10.0 lb/gal x x 5000 ft HP = 2600 psi b) Hydrostatic pressure of LEAD cement: HP, psi = 13.8 lb/gal x x 2000 ft HP = 1435 psi c) Hydrostatic pressure of TAIL cement: HP, psi = 15.8 lb/gal x x 1000 ft HP = 822 psi d) Total hydrostatic pressure in annulus: psi = 2600 psi psi psi psi = 4857 Determine the total pressure inside the casing a) Pressure exerted by the mud: HP, psi = 10.0 lb/gal x x (8000 ft 44 ft) HP = 4137 psi b) Pressure exerted by the cement: HP, psi = 15.8 lb/gal x x 44 ft HP = 36psi c) Total pressure inside the casing: psi = 4137 psi + 36 psi psi =

53 Differential pressure P D = 4857 psi 4173 psi P D = 684 psi 13. Hydraulicing Casing These calculations will determine if the casing will hydraulic out (move upward) when cementing Determine the difference in pressure gradient, psi/ft, between the cement and the mud psi/ft = (cement wt, ppg mud wt, ppg) x Determine the differential pressure (DP) between the cement and the mud DP, psi = difference in pressure gradients, psi/ft x casing length, ft Determine the area, sq in., below the shoe Area, sq in. = casing diameter, in. 2 x Determine the Upward Force (F), lb. This is the weight, total force, acting at the bottom of the shoe Force, lb = area, sq in. x differential pressure between cement and mud, psi Determine the Downward Force (W), lb. This is the weight of the casing Weight, lb = casing wt, lb/ft x length, ft x buoyancy factor Determine the difference in force, lb Differential force, lb = upward force, lb downward force, lb Pressure required to balance the forces so that the casing will not hydraulic out (move upward) psi = force, lb area, sq in. Mud weight increase to balance pressure 52

54 Mud wt, ppg = pressure required casing length, ft to balance forces, psi New mud weight, ppg Mud wt, ppg = mud wt increase, ppg mud wt, ppg Check the forces with the new mud weight a) psi/ft = (cement wt, ppg mud wt, ppg) x b) psi = difference in pressure gradients, psi/ft x casing length, ft c) Upward force, lb = pressure, psi x area, sq in. d) Difference in = upward force, lb downward force, lb force, lb Example: Casing size = 13 3/8 in. 54 lb/ft Cement weight = 15.8 ppg Mud weight = 8.8 ppg Buoyancy factor = Well depth = 164 ft (50 m) Determine the difference in pressure gradient, psi/ft, between the cement and the mud psi/ft = ( ) x psi/ft = Determine the differential pressure between the cement and the mud psi = psi/ft x 164 ft psi = 60 Determine the area, sq in., below the shoe area, sq in. = x area, = sq in. Determine the upward force. This is the total force acting at the bottom of the shoe Force, lb = sq in. x 60 psi Force = 8430 lb Determine the downward force. This is the weight of the casing Weight, lb = 54.5 lb/ft x 164 ft x Weight = 7737 lb Determine the difference in force, lb Differential force, lb = downward force, lb upward force, lb Differential force, lb = 7737 lb 8430 lb Differential force = 693 lb 53

55 Therefore: Unless the casing is tied down or stuck, it could possibly hydraulic out (move upward). Pressure required to balance the forces so that the casing will not hydraulic out (move upward) psi = 693 lb : sq in. psi = 4.9 Mud weight increase to balance pressure Mud wt, ppg = 4.9 psi : ft Mud wt = 0.57 ppg New mud weight, ppg New mud wt, ppg = 8.8 ppg ppg New mud wt = 9.4 ppg Check the forces with the new mud weight a) psi/ft = ( ) x psi/ft = b) psi = psi/ft x 164 ft psi = c) Upward force, lb = psi x sq in. Upward force = 7668 lb d) Differential force, lb = downward force upward force Differential force, lb = 7737 lb 7668 lb Differential force = + 69 lb 14. Depth of a Washout Method 1 Pump soft line or other plugging material down the drill pipe and notice how many strokes are required before the pump pressure increases. Depth of washout, ft = strokes required x pump output, bbl/stk drill pipe capacity, bbl/ft Example: Drill pipe = 3-1/2 in lb/ft Capacity = bbl/ft Pump output = bbl/stk (5-1/2 in. by 14 in. 90% efficiency) NOTE: A pressure increase was noticed after 360 strokes. 54

56 Depth of washout, ft = 360 stk x bbl/stk bbl/ft Depth of washout = 5434 ft Method 2 Pump some material that will go through the washout, up the annulus and over the shale shaker. This material must be of the type that can be easily observed as it comes across the shaker. Examples: carbide, corn starch, glass beads, bright coloured paint, etc. Depth of = strokes x pump output, (drill pipe capacity, bbl/ft + annular capacity, bbl/ft) washout, ft required bbl/stk Example: Drill pipe = 3-1/2 in lb/ft capacity = bbl/ft Pump output = bbl/stk (5-1/2 in. x 14 in. 90% efficiency) Annulus hole size = 8-1/2 in. Annulus capacity = bbl/ft (8-1/2 in. x 3-1/2 in.) NOTE: The material pumped down the drill pipe was noticed coming over the shaker after 2680 strokes. Drill pipe capacity plus annular capacity: bbl/ft bbl/ft = bbl/ft Depth of washout, ft = 2680 stk x bbl/stk bbl/ft Depth of washout = 4569 ft 15. Lost Returns Loss of Overbalance Number of feet of water in annulus Feet = water added, bbl annular capacity, bbl/ft Bottomhole (BHP) pressure reduction BHP decrease, psi = (mud wt, ppg wt of water, ppg) x x (ft of water added) Equivalent mud weight at TD EMW, ppg = mud wt, ppg (BHP decrease, psi TVD, ft) Example: Mud weight = 12.5 ppg Water added = 150 bbl required to fill annulus Weight of water = 8.33 ppg Annular capacity = bbl/ft (12-1/4 x 5.0 in.) TVD = 10,000 ft Number of feet of water in annulus 55

57 Feet = 150 bbl bbl/ft Feet = 1173 Bottomhole pressure decrease BHP decrease, psi = (12.5 ppg 8.33 ppg) x x 1173 ft BHP decrease = 254 psi Equivalent mud weight at TD EMW, ppg = 12.5 (254 psi ,000 ft) EMW = 12.0 ppg 16. Stuck Pipe Calculations Determine the feet of free pipe and the free point constant Method 1 The depth at which the pipe is stuck and the number of feet of free pipe can be estimated by the drill pipe stretch table below and the following formula. Table 2-2 Drill Pipe Stretch Table ID, in. Nominal Weight, lb/ft ID, in. Wall Area, sq in. Stretch Constant in/1000 lb /1000 ft Free Point constant 2-3/ / / / / /

58 Feet of stretch, in. x free point constant free pipe pull force in thousands of pounds Example: 3-1/2 in lb/ft drill pipe 20 in. of stretch with 35,000 lb of pull force From drill pipe stretch table: Free point constant = for 3-1/2 in. drill pipe lb/ft Feet of free pipe = 20 in. x Feet of free pipe = 5173 ft Determine free point constant (FPC) The free point constant can be determined for any type of steel drill pipe if the outside diameter, in., and inside diameter, in., are known: FPC = As x 2500 where: As = pipe wall cross sectional area, sq in. Example 1: From the drill pipe stretch table: 4-1/2 in. drill pipe 16.6 lb/ft ID = in. FPC = ( x ) x 2500 FPC = x 2500 FPC = 11,017.5 Example 2: Determine the free point constant and the depth the pipe is stuck using the following data: 2-3/8 in. tubing 6.5 lb/ft ID = in. 25 in. of stretch with 20,000 lb of pull force a) Determine free point constant (FPC): FPC = ( x ) x 2500 FPC = x 2500 FPC = 4530 b) Determine the depth of stuck pipe: Feet of free pipe = 25 in. x Feet Feet of free pipe = 5663 ft Method 2 Free pipe, ft = 735,294 x e x Wdp 57

59 differential pull, lb where e = pipe stretch, in. Wdp = drill pipe weight, lb/ft (plain end) Plain end weight, lb/ft, is the weight of drill pipe excluding tool joints: Weight, lb/ft = 2.67 x pipe OD, in. 2 pipe; ID, in. 2 Example: Determine the feet of free pipe using the following data: 5.0 in. drill pipe; ID in.; 19.5 lb/ft Differential stretch of pipe = 24 in. Differential pull to obtain stretch = 30,000 lb Weight, lb/ft = 2.67 x ( ) Weight = lb/ft Free pipe, ft = 735,294 x 24 x ,000 Free pipe = 10,547 ft Determine the height, ft of unweighted spotting fluid that will balance formation pressure in the annulus: a) Determine the difference in pressure gradient, psi/ft, between the mud weight and the spotting fluid: psi/ft = (mud wt, ppg spotting fluid wt, ppg) x b) Determine the height, ft, of unweighted spotting fluid that will balance formation pressure in the annulus: Height ft = amount of overbalance, psi difference in pressure gradient, psi/ft Example. Use the following data to determine the height, ft, of spotting fluid that will balance formation pressure in the annulus: Data: Mud weight = 11.2 ppg Weight of spotting fluid = 7.0 ppg Amount of overbalance = psi a) Difference in pressure gradient, psi/ft: psi/ft = (11.2 ppg 7.0 ppg) x psi/ft = a) Determine the height, ft. of unweighted spotting fluid that will balance formation pressure 58

60 in the annulus: Height, ft = 225 psi psi/ft Height = 1030 ft Therefore: Less than 1030 ft of spotting fluid should be used to maintain a safety factor to prevent a kick or blow-out. 17. Calculations Required for Spotting Pills The following will be determined: a) Barrels of spotting fluid (pill) required b) Pump strokes required to spot the pill Step 1 Determine the annular capacity, bbl/ft, for drill pipe and drill collars in the annulus: Annular capacity, bbl/ft = Dh in. 2 Dp in Step 2 Determine the volume of pill required in the annulus: Vopl bbl = annular capacity, bbl/ft x section length, ft x washout factor Step 3 Determine total volume, bbl, of spotting fluid (pill) required: Barrels = Barrels required in annulus plus barrels to be left in drill string Step 4 Determine drill string capacity, bbl: Barrels = drill pipe/drill collar capacity, bbl/ft x length, ft Step 5 Determine strokes required to pump pill: Strokes = vol of pill, bbl pump output, bbl/stk Step 6 Determine number of barrels required to chase pill: Barrels = drill string vol, bbl vol left in drill string, bbl 59

61 Step 7 Determine strokes required to chase pill: Strokes = bbl required to pump output, + strokes required to chase pill bbl/stk displace surface system Step 8 Total strokes required to spot the pill: Total strokes = strokes required to pump pill + strokes required to chase pill Example: Drill collars are differentially stuck. Use the following data to spot an oil based pill around the drill collars plus 200 ft (optional) above the collars. Leave 24 bbl in the drill string: Data: Well depth = 10,000 ft Pump output = bbl/stk Hole diameter = 8-1/2 in. Washout factor = 20% Drill pipe = 5.0 in lb/ft Drill collars = 6-1/2 in. OD x 2-1/2 in. ID capacity = bbl/ft capacity = bbl/ft length = 9400 ft length = 600 ft Strokes required to displace surface system from suction tank to the drill pipe = 80 stk. Step 1 Annular capacity around drill pipe and drill collars: a) Annular capacity around drill collars: Annular capacity, bbl/ft = Annular capacity = bbl/ft b) Annular capacity around drill pipe: Annular capacity, bbl/ft = Annular capacity = bbl/ft Step 2 Determine total volume of pill required in annulus: a) Volume opposite drill collars: Vol, bbl = bbl/ft x 600 ft x 1.20 Vol = 21.0 bbl b) Volume opposite drill pipe: Vol, bbl = bbl/ft x 200 ft x 1.20 Vol = 11.0 bbl c) Total volume bbl, required in annulus: Vol, bbl = 21.0 bbl bbl Vol = 32.0 bbl 60

62 Step 3 Total bbl of spotting fluid (pill) required: Barrels = 32.0 bbl (annulus) bbl (drill pipe) Barrels = 56.0 bbl Step 4 Determine drill string capacity: a) Drill collar capacity, bbl: Capacity, bbl = bbl/ft x 600 ft Capacity = 3.72 bbl b) Drill pipe capacity, bbl: Capacity, bbl = bbl/ft x 9400 ft Capacity = bbl c) Total drill string capacity, bbl: Capacity, bbl = 3.72 bbl bbl Capacity = bbl Step 5 Determine strokes required to pump pill: Strokes = 56 bbl bbl/stk Strokes = 479 Step 6 Determine bbl required to chase pill: Barrels = bbl 24 bbl Barrels = Step 7 Determine strokes required to chase pill: Strokes = bbl bbl/stk + 80 stk Strokes = 1333 Step 8 Determine strokes required to spot the pill: Total strokes = Total strokes = Pressure Required to Break Circulation Pressure required to overcome the mud s gel strength inside the drill string 61

63 Pgs = (y 300 d) L where Pgs = pressure required to break gel strength, psi y = 10 mm gel strength of drilling fluid, lb/100 sq ft d = inside diameter of drill pipe, in. L = length of drill string, ft Example: y = 10 lb/100 sq ft d = in. L= 12,000 ft Pgs = ( ) 12,000 ft Pgs = x 12,000 ft Pgs = 93.5 psi Therefore, approximately 94 psi would be required to break circulation. Pressure required to overcome the mud s gel strength in the annulus Pgs = y [300 (Dh, in. Dp, in.)] x L where Pgs = pressure required to break gel strength, psi L = length of drill string, ft y = 10 mm. gel strength of drilling fluid, lb/100 sq ft Dh = hole diameter, in. Dp = pipe diameter, in. Example: L = 12,000 ft Dh = 12-1/4 in. y = 10 lb/100 sq ft Dp = 5.0 in. Pgs = 10 [300 x ( )] x 12,000 ft Pgs = x 12,000 ft Pgs = 55.2 psi Therefore, approximately 55 psi would be required to break circulation. References API Specification for Oil- Well Cements and Cement Additives, American Petroleum Institute, New York, N.Y., Chenevert, Martin E. and Reuven Hollo, TI-59 Drilling Engineering Manual, Penn Well Publishing Company, Tulsa,

64 Crammer Jr., John L., Basic Drilling Engineering Manual, PennWell Publishing Company, Tulsa, Drilling Manual, International Association of Drilling Contractors, Houston, Texas, Murchison, Bill, Murchison Drilling Schools Operations Drilling Technology and Well Control Manual, Albuquerque, New Mexico. Oil-Well Cements and Cement Additives, API Specification BA, December CHAPTER THREE DRILLING FLUIDS 63

65 1. Increase Mud Density Mud weight, ppg, increase with barite (average specific gravity of barite - 4.2) Barite, sk/100 bbl = 1470 (W 2 W 1 ) 35 W 2 Example: Determine the number of sacks of barite required to increase the density of 100 bbl of 12.0 ppg (W 1 ) mud to 14.0 ppg (W 2 ): Barite sk/100 bbl = 1470 ( ) Barite, sk/100 bbl = Barite = 140 sk/ 100 bbl Volume increase, bbl, due to mud weight increase with barite Volume increase, per 100 bbl = 100 (W 2 W 1 ) 35 W 2 Example: Determine the volume increase when increasing the density from 12.0 ppg (W 1 ) to 14.0 ppg (W 2 ): Volume increase, per 100 bbl = 100 ( ) Volume increase, per 100 bbl =

66 Volume increase = 9.52 bbl per 100 bbl Starting volume, bbl, of original mud weight required to give a predetermined final volume of desired mud weight with barite Starting volume, bbl = V F (35 W 2 ) 35 W 1 Example: Determine the starting volume, bbl, of 12.0 ppg (W 1 ) mud required to achieve 100 bbl (V F ) of 14.0 ppg (W 2 ) mud with barite: Starting volume, bbl = 100 ( ) Starting volume, bbl = Starting volume = 91.3 bbl Mud weight increase with calcium carbonate (SG 2.7) NOTE: The maximum practical mud weight attainable with calcium carbonate is 14.0 ppg. Sacks/ 100 bbl = 945(W 2 W 1 ) 22.5 W 2 Example: Determine the number of sacks of calcium carbonate/l00 bbl required to increase the density from 12.0 ppg (W 1 ) to 13.0 ppg (W 2 ): Sacks/ 100 bbl = 945 ( ) Sacks/ 100 bbl = Sacks/ 100 bbl = 99.5 Volume increase, bbl, due to mud weight increase with calcium carbonate Volume increase, per 100 bbl =100 (W 2 W 1 ) 22.5 W 2 Example. Determine the volume increase, bbl/100 bbl, when increasing the density from 12.0 ppg (W 3 ) to 13.0 ppg (W 2 ): Volume increase, per 100 bbl =100 ( ) Volume increase, per 100 bbl =

67 Volume increase = bbl per 100 bbl Starting volume, bbl, of original mud weight required to give a predetermined final volume of desired mud weight with calcium carbonate Starting volume, bbl = V F (22.5 W2) 22.5 W 1 Example: Determine the starting volume, bbl, of 12.0 ppg (W 1 ) mud required to achieve 100 bbl (V F ) of 13.0 ppg (W 2 ) mud with calcium carbonate: Starting volume, bbl = 100 ( ) Starting volume, bbl = Starting volume = 90.5 bbl Mud weight increase with hematite (SG 4.8) Hematite, sk/100 bbl = 1680 (W 2 W~) 40 W 2 Example: Determine the hematite, sk/100 bbl, required to increase the density of 100 bbl of 12.0 ppg (W 1 ) to 14.0 ppg (W 2 ): Hematite, sk/100 bbl = 1680 ( ) Hematite, sk/100 bbl = Hematite = sk/100 bbl Volume increase, bbl, due to mud weight increase with hematite Volume increase, per 100 bbl = l00 (W 2 W 1 ) 40 W 2 Example: Determine the volume increase, bbl/100 bbl, when increasing the density from 12.0 ppg (W,) to 14.0 ppg (W 2 ): Volume increase, per 100 bbl = 100 ( ) Volume increase, per 100 bbl = Volume increase = 7.7 bbl per 100 bbl 66

68 Starting volume, bbl, of original mud weight required to give a predetermined final volume of desired mud weight with hematite Starting volume, bbl = V F (40.0 W2) 40 W 1 Example: Determine the starting volume, bbl, of 12.0 ppg (W 1 ) mud required to achieve 100 bbl (V F ) of 14.0 ppg (W 2 ) mud with hematite: Starting volume, bbl = 100 ( ) Starting volume, bbl = Starting volume = 92.9 bbl 2. Dilution Mud weight reduction with water Water, bbl = V 1 (W 1 W 2 ) W 2 Dw Example: Determine the number of barrels of water weighing 8.33 ppg (Dw) required to reduce 100 bbl (V 1 ) of 14.0 ppg (W 1 ) to 12.0 ppg (W 2 ): Water, bbl = 100 ( ) Water, bbl = Water = 54.5 bbl Mud weight reduction with diesel oil Diesel, bbl = V 1 (W 1 W 2 ) W 2 Dw Example: Determine the number of barrels of diesel weighing 7.0 ppg (Dw) required to reduce 100 bbl (V 1 ) of 14.0 ppg (W 1 ) to 12.0 ppg (W 2 ): Diesel, bbl = 100 ( )

69 Diesel, bbl = Diesel = 40 bbl 3. Mixing Fluids of Different Densities Formula: (V 1 D 1 ) + (V 2 D 2 ) = V F D F where V 1 = volume of fluid 1 (bbl, gal, etc.) V 2 = volume of fluid 2 (bbl, gal, etc.) V F = volume of final fluid mix D 1 = density of fluid 1 (ppg,lb/ft 3, etc.) D 2 = density of fluid 2 (ppg,lb/ft 3, etc.) D F = density of final fluid mix Example 1: A limit is placed on the desired volume: Determine the volume of 11.0 ppg mud and 14.0 ppg mud required to build 300 bbl of 11.5 ppg mud: Given: 400 bbl of 11.0 ppg mud on hand, and 400 bbl of 14.0 ppg mud on hand Solution: let V 1 = bbl of 11.0 ppg mud V 2 = bbl of 14.0 ppg mud then a) V 1 + V 2 = 300 bbl b) (11.0) V 1 + (14.0) V 2 = (11.5)(300) Multiply Equation A by the density of the lowest mud weight (D 1 = 11.0 ppg) and subtract the result from Equation B: b) (11.0) (V 1 ) + (14.0) (V 2 ) = 3450 a) (11.0) (V 1 ) + (11.0) (V 2 ) = (3.0) (V 2 ) = V 2 = 150 V 2 = V 2 = 50 Therefore: V 2 = 50 bbl of 14.0 ppg mud V 1 + V 2 = 300 bbl V 1 = V 1 = 250 bbl of 11.0 ppg mud Check: V 1 = 50 bbl D 1 = 14.0 ppg V 2 = 150 bbl D 2 = 11.0 ppg V F = 300 bbl D F = final density, ppg (50) (14.0) + (250) (11.0) = 300 D F = 300 D F 68

70 3450 = 300 D F = D F 11.5 ppg = D F Example 2: No limit is placed on volume: Determine the density and volume when the two following muds are mixed together: Given: 400 bbl of 11.0 ppg mud, and 400 bbl of 14.0 ppg mud Solution: let V 1 = bbl of 11.0 ppg mud D 1 = density of 11.0 ppg mud V 2 = bbl of 14.0 ppg mud D 2 = density of 14.0 ppg mud V F = final volume, bbl D F = final density, ppg Formula: (V 1 D 1 ) + (V 2 D 2 ) = V F D F (400) (l1.0) + (400) (l4.0) = 800 D F = 800 D F 10,000 = 800 D F 10, = D F 12.5 ppg = D F Therefore: final volume = 800 bbl final density = 12.5 ppg 4. Oil Based Mud Calculations Density of oil/water mixture being used (V 1 )(D,) + (V 2 )(D 2 ) = (V~ + V 2 )D F Example: If the oil/water (o/w) ratio is 75/25 (75% oil, V 1, and 25% water V 2 ), the following material balance is set up: NOTE: The weight of diesel oil, D 1 = 7.0 ppg The weight of water, D 2 = 8.33 ppg (0.75) (7.0) + (0.25) (8.33) = ( ) D F = 1.0 D F 7.33 = D F Therefore: The density of the oil/water mixture = 7.33 ppg Starting volume of liquid (oil plus water) required to prepare a desired volume of mud SV= 35 W 2 x DV 35 W 1 69

71 where SV = starting volume, bbl W 2 = desired density, ppg W 1 = initial density of oil/water mixture, ppg Dv = desired volume, bbl Example: W 1 = 7.33 ppg (o/w ratio 75/25) W 2 = 16.0 ppg Dv = 100 bbl Solution: SV = x SV = 19 x SV = x 100 SV = 68.7 bbl Oil/water ratio from retort data Obtain the percent-by-volume oil and percent-by-volume water from retort analysis or mud still analysis. From the data obtained, the oil/water ratio is calculated as follows: a) % oil in liquid phase = % by vol oil x 100 % by vol oil + % by vol water b) % water in liquid phase = % by vol water x 100 % by vol oil + % by vol water c) Result: The oil/water ratio is reported as the percent oil and the percent water. Example: Retort analysis: % by volume oil = 51 % by volume water = 17 % by volume solids = 32 Solution: a) % oil in liquid phase = 51 x x 17 % oil in liquid phase = 75 b) % water in liquid phase = 17 x % water in liquid phase = 25 c) Result: Therefore, the oil/water ratio is reported as 75/25: 75% oil and 25% water. Changing oil/water ratio NOTE: If the oil/water ratio is to be increased, add oil; if it is to be decreased, add water. 70

72 Retort analysis: % by volume oil = 51 % by volume water = 17 % by volume solids = 32 The oil/water ratio is 75/25. Example 1: Increase the oil/water ratio to 80/20: In 100 bbl of this mud, there are 68 bbl of liquid (oil plus water). To increase the oil/water ratio, add oil. The total liquid volume will be increased by the volume of the oil added, but the water volume will not change. The 17 bbl of water now in the mud represents 25% of the liquid volume, but it will represent only 20% of the new liquid volume. Therefore: let x = final liquid volume then, 0.20x = 17 x = 17 : 0.20 x = 85 bbl The new liquid volume = 85 bbl Barrels of oil to be added: Oil, bbl = new liquid vol original liquid vol Oil, bbl = Oil = 17 bbl oil per 100 bbl of mud Check the calculations. If the calculated amount of liquid is added, what will be the resulting oil/water ratio? % oil in liquid phase = original vol oil + new vol oil x 100 original liquid oil + new oil added % oil in liquid phase = x % oil in liquid phase = 80 % water would then be: = 20 Therefore: The new oil/water ratio would be 80/20. Example 2: Change the oil/water ratio to 70/30: As in Example I, there are 68 bbl of liquid in 100 bbl of this mud. In this case, however, water will be added and the volume of oil will remain constant. The 51 bbl of oil represents 75% of the original liquid volume and 70% of the final volume: Therefore: let x = final liquid volume then, 0.70x = 51 x = 51 :

73 x = 73 bbl Barrels of water to be added: Water, bbl = new liquid vol original liquid vol Water, bbl = Water = 5 bbl of water per 100 bbl of mud Check the calculations. If the calculated amount of water is added, what will be the resulting oil/water ratio? % water in liquid phase = x % water in liquid = 30 % oil in liquid phase = = 70 Therefore, the new oil/water ratio would be 70/ Solids Analysis Basic solids analysis calculations NOTE: Steps 1 4 are performed on high salt content muds. For low chloride muds begin with Step 5. Step 1 Percent by volume saltwater (SW) SW = (5.88 x 10-8 ) x [(ppm Cl) ] x % by vol water Step 2 Percent by volume suspended solids (SS) SS = 100 %by vol oil % by vol SW Step 3 Average specific gravity of saltwater (ASGsw) ASGsw = (ppm Cl) 0.95 x (1.94 x 10-6) + 1 Step 4 Average specific gravity of solids (ASG) ASG = (12 x MW) (% by vol SW x ASGsw) (0.84 x % by vol oil) SS Step 5 Average specific gravity of solids (ASG) ASG = (12 x MW) % by vol water % by vol oil % by vol solids 72

74 Step 6 Percent by volume low gravity solids (LGS) LGS = % by volume solids x (4.2 ASG) 1.6 Step 7 Percent by volume barite Barite, % by vol = % by vol solids % by vol LGS Step 8 Pounds per barrel barite Barite, lb/bbl = % by vol barite x Step 9 Bentonite determination If cation exchange capacity (CEC)/methytene blue test (MBT) of shale and mud are KNOWN: a) Bentonite, lb/bbl: Bentonite, lb/bbl = 1 : (1 (S : 65) x (M 9 x (S : 65)) x % by vol LGS Where S = CEC of shale M = CEC of mud b) Bentonite, % by volume: Bent, % by vol = bentonite, lb/bbl 9.1 If the cation exchange capacity (CEC)/methylene blue (MBT) of SHALE is UNKNOWN: a) Bentonite, % by volume = M % by volume LGS 8 where M = CEC of mud b) Bentonite, lb/bbl = bentonite, % by vol x 9.1 Step 10 Drilled solids, % by volume Drilled solids, % by vol = LGS, % by vol bentonite, % by vol Step 11 Drilled solids, lb/bbl Drilled solids, lb/bbl = drilled solids, % by vol x 9.1 Example: Mud weight = 16.0 ppg Chlorides = 73,000 ppm CEC of mud = 30 lb/bbl CEC of shale = 7 lb/bbl Retort Analysis: water = 57.0% by volume oil = 7.5% by volume solids = 35.5% by volume 1. Percent by volume saltwater (SW) 73

75 SW = [(5.88 x 10-8 )(73,000) ] x 57 SW = [( x ) + 1] x 57 SW = ( ) x 57 SW = percent by volume 2. Percent by volume suspended solids (SS) SS = SS = percent by volume 3. Average specific gravity of saltwater (ASGsw) ASGsw = [(73,000) 0.95 (1.94 x 10-6 )] + 1 ASGsw = (41, x l.94-6 ) + 1 ASGsw = I ASGsw = Average specific gravity of solids (ASG) ASO = (12 x 16) ( x ) (0.84 x 7.5) ASG = ASG = Because a high chloride example is being used, Step 5 is omitted. 6. Percent by volume low gravity solids (LGS) LGS = x ( ) 1.6 LGS = percent by volume 7. Percent by volume barite Barite, % by volume = Barite = % by volume 8. Barite, lb/bbl Barite, lb/bbl = x Barite = lb/bbl 9. Bentonite determination a) lb/bbl = 1 : (1 (7 : 65) x (30 9 x (7 : 65)) x lb/bbl = x x

76 Bent = lb/bbl b) Bentonite, % by volume Bent, % by vol = : 9.1 Bent = % by vol 10. Drilled solids, percent by volume Drilled solids, % by vol = Drilled solids = 8.047% by vol 11. Drilled solids, pounds per barrel Drilled solids, lb/bbl = x 9.1 Drilled solids = lb/bbl 6. Solids Fractions Maximum recommended solids fractions (SF) SF = (2.917 x MW) Maximum recommended low gravity solids (LGS) LGS = ((SF : 100) [ x ((MW : 8.33) 1)]) x 200 where SF = maximum recommended solids fractions, % by vol LGS = maximum recommended low gravity solids, % by vol MW = mud weight, ppg Example: Determine: Mud weight = 14.0 ppg Maximum recommended solids, % by volume Low gravity solids fraction, % by volume Maximum recommended solids fractions (SF), % by volume: SF = (2.917 x 14.0) SF = SF = % by volume Low gravity solids (LOS), % by volume: LGS = ((26.67 : 100) [ x ((14.0 : 8.33) 1)]) x 200 LGS = ( x ) x

77 LGS = ( ) x 200 LGS = x 200 LGS = 10.8 % by volume 7. Dilution of Mud System Vwm = Vm (Fct Fcop) Fcop Fca where Vwm = barrels of dilution water or mud required Vm = barrels of mud in circulating system Fct = percent low gravity solids in system Fcop = percent total optimum low gravity solids desired Fca = percent low gravity solids (bentonite and/or chemicals added) Example: 1000 bbl of mud in system. Total LOS = 6%. Reduce solids to 4%. Dilute with water: Vwm = 1000 (6 4) 4 Vwm = Vwm = 500 bbl If dilution is done with a 2% bentonite slurry, the total would be: Vwm = 1000 (6 4) 4 2 Vwm = Vwm = 1000 bbl 8. Displacement Barrels of Water/Slurry Required Vwm = Vm (Fct Fcop) Fct Fca where Vwm = barrels of mud to be jetted and water or slurry to be added to maintain constant circulating volume: 76

78 Example: 1000 bbl in mud system. Total LGS = 6%. Reduce solids to 4%: Vwm = 1000 (6 4) 6 Vwm = Vwm = 333 bbl If displacement is done by adding 2% bentonite slurry, the total volume would be: Vwm = 1000(6 4) 6 2 Vwm = Vwm = 500 bbl 9. Evaluation of Hydrocyclone Determine the mass of solids (for an unweighted mud) and the volume of water discarded by one cone of a hydrocyclone (desander or desilter): Volume fraction of solids (SF): SF = MW Mass rate of solids (MS): Volume rate of water (WR) MS = 19,530 x SF x V T WR = 900 (1 SF) V T where SF = fraction percentage of solids MW = average density of discarded mud, ppg MS = mass rate of solids removed by one cone of a hydrocyclone, lb/hr V = volume of slurry sample collected, quarts T = time to collect slurry sample, seconds WR = volume of water ejected by one cone of a hydrocyclone, gal/hr Example: Average weight of slurry sample collected = 16.0 ppg Sample collected in 45 seconds Volume of slurry sample collected 2 quarts a) Volume fraction of solids: SF =

79 SF = b) Mass rate of solids: MS = 19,530 x x MS = 11, x MS = lb/hr c) Volume rate of water: WR = 900 ( ) WR = 900 x x WR = 17.0 gal/hr 10. Evaluation of Centrifuge a) Underflow mud volume: QU = [ QM x (MW PO)] [QW x (PO PW)] PU PO b) Fraction of old mud in Underflow: FU = 35 PU. 35 MW + ( QW : QM) x (35 PW) c) Mass rate of clay: QC = CC x [QM (QU x FU)] 42 d) Mass rate of additives: QC = CD x [QM (QU x FU)] 42 e) Water flow rate into mixing pit: QP = [QM x (35 MW)] [QU x (35 PU)] ( x QC) ( x QD) 35 PW f) Mass rate for API barite: QB = QM QU QP QC QD x where : MW = mud density into centrifuge, ppg QM = mud volume into centrifuge, gal/m PU = Underflow mud density, ppg PW = dilution water density, ppg 78

80 QW = dilution water volume, gal/mm PO = overflow mud density, ppg CD = additive content in mud, lb/bbl CC = clay content in mud, lb/bbl QU = Underflow mud volume, gal/mm QC = mass rate of clay, lb/mm FU = fraction of old mud in Underflow QD = mass rate of additives, lb/mm QB = mass rate of API barite, lb/mm QP = water flow rate into mixing pit, gal/mm Example: Mud density into centrifuge (MW) = 16.2 ppg Mud volume into centrifuge (QM) = 16.5 gal/mm Dilution water density (PW) = 8.34 ppg Dilution water volume (QW) = 10.5 gal/mm Underfiow mud density (PU) = 23.4 ppg Overflow mud density (P0) = 9.3 ppg Clay content of mud (CC) = 22.5 lb/bbl Additive content of mud (CD) = 6 lb/bbl Determine: Flow rate of Underflow Volume fraction of old mud in the Underflow Mass rate of clay into mixing pit Mass rate of additives into mixing pit Water flow rate into mixing pit Mass rate of API barite into mixing pit a) Underfiow mud volume, gal/mm: QU = [ 16.5 x ( )] [ 10.5 x ( ) ] QU = QU = 7.4 gal/mm b) Volume fraction of old mud in the Underflow: FU = [ (10.5 : 16.5) x ( )] FU = ( x 26.66) FU = 0.324% c) Mass rate of clay into mixing pit, lb/mm: QC = 22.5 x [16.5 (7.4 x 0.324)] 42 QC = 22.5 x QC = 7.55 lb/min 79

81 d) Mass rate of additives into mixing pit, lb/mm: QD = 6 x [16.5 (7.4 x 0.324)] 42 QD = 6 x QD = 2.01 lb/mm e) Water flow into mixing pit, gal/mm: QP = [16.5 x ( )] [7.4 x ( )] ( x 7.55) ( x 2) ( ) QP = QP = QP = 8.20 gal/mm f) Mass rate of API barite into mixing pit, lb/mm: QB = l (7.55 : 21.7) (2.01 : 21.7) x 35 QB = x 35 QB = x 35 QB = lb/mm References Chenevert, Martin E., and Reuven Hollo, TI-59 Drilling Engineering Manual, PennWell Publishing Company, Tulsa, Crammer Jr., John L. Basic Drilling Engineering Manual, PennWell Publishing Company, Tulsa, Manual of Drilling Fluids Technology, Baroid Division, N.L. Petroleum Services, Houston, Texas, Mud Facts Engineering Handbook, Milchem Incorporated, Houston, Texas,

82 CHAPTER FOUR PRESSURE CONTROL 81

83 1. Kill Sheets and Related Calculations Normal Kill Sheet Pre-recorded Data Original mud weight (OMW) ppg Measured depth (MD) ft Kill rate pressure (KRP) spm Kill rate pressure (KRP) spm Drill String Volume Drill pipe capacity bbl/ft x length, ft = bbl Drill pipe capacity bbl/ft x length, ft = bbl Drill collar capacity bbl/ft x length, ft = bbl Total drill string volume bbl 82

84 Annular Volume Drill collar/open hole Capacity bbl/ft x length, ft = bbl Drill pipe/open hole Capacity bbl/ft x length, ft = bbl Drill pipe/casing Capacity bbl/ft x length, ft = bbl Total barrels in open hole bbl Total annular volume bbl Pump Data Pump output % efficiency Surface to bit strokes: Drill string volume bbl pump output, bbl/stk = stk Bit to casing shoe strokes: Open hole volume bbl pump output, bbl/stk = stk Bit to surface strokes: Annulus volume bbl pump output, bbl/stk = stk Maximum allowable shut-in casing pressure: Leak-off test psi, using ppg mud casing setting depth of TVD Kick data SIDPP psi SICP psi Pit gain bbl True vertical depth ft Calculations Kill Weight Mud (KWM) 83

85 = SIDPP psi TVD ft + OMW ppg = ppg Initial Circulating Pressure (ICP) = SIDPP psi + KRP psi = psi Final Circulating Pressure (FCP) = KWM ppg x KRP psi OMW ppg = psi Psi/stroke ICP psi FCP psi strokes to bit = psi/stk Pressure Chart Strokes Pressure 0 < Initial Circulating Pressure Strokes to Bit > <Final Circulating Pressure Example: Use the following data and fill out a kill sheet: Data: Original mud weight Measured depth Kill rate 50 spm Kill rate 30 spm Drill string: = 9.6 ppg = 10,525 ft = 1000 psi = 600 psi 84

86 drill pipe 5.0 in lb/ft capacity HWDP 5.0 in lb/ft capacity length drill collars 8.0 in. OD 3.0 in. ID capacity length Annulus: hole size drill collar/open hole capacity drill pipe/open hole capacity drill pipe/casing capacity Mud pump (7 in. x 12 in. 95% eff.) Leak-off test with 9,0 ppg mud Casing setting depth Shut-in drill pipe pressure Shut-in casing pressure Pit volume gain True vertical depth = bbl/ft = bbl/ft = 240 ft = bbl/ft = 360 ft = 12 1/4 in. = bbl/ft = bbl/ft = bbl/ft = bbl/stk = 1130 psi = 4000 ft = 480 psi = 600 psi = 35 bbl = 10,000 ft Calculations Drill string volume: Drill pipe capacity bbl/ft x 9925 ft = bbl HWDP capacity bbl/ft x 240 ft = 2.12 bbl Drill collar capacity bbl/ft x 360 ft = 3.13 bbl Total drill string volume = bbl Annular volume: Drill collar/open hole bbl/ft x 360 ft = bbl Drill pipe/open hole bbl/ft x 6165 ft = bbl Drill pipe/casing bbl/ft x 4000 ft = bbl Total annular volume = bbl Strokes to bit: Drill string volume bbl bbl/stk Strokes to bit = 1335 stk Bit to casing strokes: Open hole volume = bbl bbl/stk 85

87 Bit to casing strokes = 5729 stk Bit to surface strokes: Annular volume = bbl bbl/stk Bit to surface strokes Kill weight mud (KWM) = 9561 stk 480 psi ,000 ft ppg = 10.5 ppg Initial circulating pressure (ICP) 480 psi psi = 1480 psi Final circulating pressure (FCP) 10.5 ppg x 1000 psi 9.6 ppg = 1094 psi Pressure Chart Strokes to bit = = Therefore, strokes will increase by per line: Pressure Chart Strokes rounded up = = = = = = = = = = 1335 Pressure Pressure ICP (1480) psi FCP (1094) 10 = 38.6 psi Therefore, the pressure will decrease by 38.6 psi per line. Pressure Chart 86

88 Strokes Pressure = < ICP 38.6 = = = = = = = = = = 1094 < FCP Trip Margin (TM) TM = Yield point 11.7(Dh, in. Dp, in.) Example: Yield point = 10 lb/l00 sq ft; Dh = 8.5 in.; Dp = 4.5 in. TM = ( ) TM = 0.2 ppg Determine Psi/stk psi/stk = ICP - FCP strokes to bit Example: Using the kill sheet just completed, adjust the pressure chart to read in increments that are easy to read on pressure gauges. Example: 50 psi: Data: Initial circulating pressure = 1480 psi Final circulating pressure = 1094 psi Strokes to bit = 1335 psi psi/stk = psi/stk = The pressure side of the chart will be as follows: Pressure Chart Strokes Pressure

89 Adjust the strokes as necessary. For line 2: How many strokes will be required to decrease the pressure from 1480 psi to 1450 psi? 1480 psi 1450 psi = 30 psi 30 psi psi/stk = 104 strokes For lines 3 to 7: How many strokes will be required to decrease the pressure by 50 psi increments? Therefore, the new pressure chart will be as follows: Pressure Chart Strokes Pressure = = = = = = = Kill Sheet With a Tapered String strokes = ICP [ (DPL DSL) x (ICP FCP)] Note: Whenever a kick is taken with a tapered drill string in the hole, interim pressures 88

90 should be calculated for a) the length of large drill pipe (DPL) and b) the length of large drill pipe plus the length of small drill pipe. Example: Drill pipe 1: 5.0 in lb/ft Capacity = bbl/ft Length = 7000 ft Drill pipe 2: 3-1/2 in lb/ft Capacity = bbl/ft Length = 6000 ft Drill collars: 4 1/2 in. OD x 1-1/2 in. ID Capacity = bbl/ft Length = 2000 ft Step 1 Determine strokes: 7000 ft x bbl/ft bbl/stk = ft x bbl/ft bbl/stk = ft x bbl/ft bbl/stk = 38 Total strokes = 1482 Data from kill sheet Initial drill pipe circulating pressure (ICP) = 1780 psi Final drill pipe circulating pressure (FCP) = 1067 psi Step 2 Determine interim pressure for the 5.0 in. drill pipe at 1063 strokes: 1063 strokes = 1780 [( ,000) x ( )] = 1780 ( x 713) = = 1447 psi Step 3 Determine interim pressure for 5.0 in. plus 3-1/2 in. drill pipe ( ) = 1444 strokes: 1444 strokes = 1780 [(11,300 15,000) x ( )] = 1780 ( x 713) = = 1162 psi Step 4 Plot data on graph paper 89

91 Figure 4-1. Data from kill sheet. Note. After pumping 1062 strokes, if a straight line would have been plotted, the well would have been underbalanced by 178 psi. Kill Sheet for a Highly Deviated Well Whenever a kick is taken in a highly deviated well, the circulating pressure can be excessive when the kill weight mud gets to the kick-off point (KOP). If the pressure is excessive, the pressure schedule should be divided into two sections: 1) from surface to KOP, and 2) from KOP to TD. The following calculations are used: Determine strokes from surface to KOP: Strokes = drill pipe capacity, bbl!ft x measured depth to KOP, ft x pump output, bbl/stk Determine strokes from KOP to TD: Strokes = drill string capacity, bbl/ft x measured depth to TD, ft x pump output, bbl/stk Kill weight mud: Initial circulating pressure: Final circulating pressure: KWM = SIDPP TVD + OMW ICP = SIDPP + KRP FCP KWM x KRP 0MW Hydrostatic pressure increase from surface to KOP: psi = (KWM - OMW) x x KOP 90

92 Friction pressure increase to KOP: FP = (FCP - KRP) x KOP TD Circulating pressure when KWM gets to KOP: CP ~ KOP = ICP HP increase to KOP + friction pressure increase, psi Note: At this point, compare this circulating pressure to the value obtained when using a regular kill sheet. Example: Original mud weight (OMW) = 9.6 ppg Measured depth (MD) = 15,000 ft Measured KOP = 5000 ft True vertical KOP = 5000 ft Kill rate pressure 30 spm = 600 psi Pump output = bbl/stk Drill pipe capacity = bbl/ft Shut-in drill pipe pressure (SIDPP) = 800 psi True vertical depth (TVD) = 10,000 ft Solution: Strokes from surface to KOP: Strokes = bbl/ft x 5000 ft bbl/stk Strokes = 653 Strokes from KOP to TD: Strokes = bbl/ft x 10,000 ft bbl/stk Strokes = 1306 Total strokes from surface to bit: Surface to bit strokes = Surface to bit strokes = 1959 Kill weight mud (KWM): KWM = 800 psi ,000 ft ppg KWM = 11.1 ppg Initial circulating pressure (ICP): 91

93 ICP = 800 psi psi ICP = 1400 psi Final circulating pressure (FCP): FCP = 11.1 ppg x 600 psi ± 9.6 ppg FCP = 694 psi Hydrostatic pressure increase from surface to KOP: HPi = ( ) x x 5000 HPi = 390 psi Friction pressure increase to TD: FP = ( ) x ,000 FP = 31 psi Circulating pressure when KWM gets to KOP: CP = CP = 1041 psi Compare this circulating pressure to the value obtained when using a regular kill sheet: psi/stk = psi/stk = psi/stk x 653 strokes = 235 psi = 1165 psi Using a regular kill sheet, the circulating drill pipe pressure would be 1165 psi. The adjusted pressure chart would have 1041 psi on the drill pipe gauge. This represents 124 psi difference in pressure, which would also be observed on the annulus (casing) side. It is recommended that if the difference in pressure at the KOP is 100 psi or greater, then the adjusted pressure chart should be used to minimise the chances of losing circulation. The chart below graphically illustrates the difference: 92

94 Figure 4 2. Adjusted pressure chart. 2. Pre-recorded Information Maximum Anticipated Surface Pressure Two methods are commonly used to determine maximum anticipated surface pressure: Method 1: Use when assuming the maximum formation pressure is from TD: Step 1 Determine maximum formation pressure (FPmax): FP max = (maximum mud wt to be used, ppg + safety factor, ppg) x x (total depth, ft) Step 2 Assuming 100% of the mud is blown out of the hole, determine the hydrostatic pressure in the wellbore: Note: 70% to 80% of mud being blown out is sometimes used instead of l00%. HPgas = gas gradient, psi/ft x total depth, ft Step 3 Determine maximum anticipated surface pressure (MASP): MASP = FPmax HPgas Example: Proposed total depth = 12,000 ft Maximum mud weight to be used in drilling well = 12.0 ppg 93

95 Safety factor Gas gradient = 4.0 ppg = 0.12 psi/ft Assume that 100% of mud is blown out of well. Step 1 Determine fracture pressure, psi: FPmax = ( ) x x 12,000 ft FPmax = 9984 psi Step 2 HPgas = 0.12 x 12,000 ft HPgas = 1440 psi Step 3 MASP = MASP = 8544 psi Method 2: Use when assuming the maximum pressure in the wellbore is attained when the formation at the shoe fractures: Step 1 Fracture, psi = (estimated fracture + safety factor, ppg) x x (casing shoe TVD, ft) pressure (gradient, ppg ) Note: A safety factor is added to ensure the formation fractures before BOP pressure rating is exceeded. Step 2 Determine the hydrostatic pressure of gas in the wellbore (HPgas): HPgas = gas gradient, psi/ft x casing shoe TVD, ft Step 3 Determine the maximum anticipated surface pressure (MASP), psi: Example: Proposed casing setting depth = 4000 ft Estimated fracture gradient = 14.2 ppg Safety factor = 1.0 ppg Gas gradient = 0.12 psi/ft Assume 100 / of mud is blown out of the hole. Step 1 Fracture pressure, psi = ( ) x x 4000 ft Fracture pressure, psi = 3162 psi Step 2 HPgas = 0.12 x 4000 ft HPgas = 480 psi Step 3 MASP = MASP = 2682 psi 94

96 Sizing Diverter Lines Determine diverter line inside diameter, in., equal to the area between the inside diameter of the casing and the outside diameter of drill pipe in use: Diverter line ID, in. = ~Ib~bp2 Example: Casing 13-3/8 in. J IbIft ID = in. Drill pipe 19.5 lb/ft OD = 5.0 in. Determine the diverter line inside diameter that will equal the area between the casing and drill pipe: Diverter line ID, in. = sq. root ( ) Diverter line ID = in. Formation Pressure Tests Two methods of testing: Equivalent mud weight test Leak-off test Precautions to be undertaken before testing: 1. Circulate and condition the mud to ensure the mud weight is consistent throughout the system. 2. Change the pressure gauge (if possible) to a smaller increment gauge so a more accurate measure can be determined. 3. Shut-in the well. 4. Begin pumping at a very slow rate 1/4 to 1/2 bbl/min. 5. Monitor pressure, time, and barrels pumped. 6. Some operators may have different procedures in running this test, others may include: a. Increasing the pressure by 100 psi increments, waiting for a few minutes, then increasing by another 100 psi, and so on, until either the equivalent mud weight is achieved or until Leak-off is achieved. b. Some operators prefer not pumping against a closed system. They prefer to circulate through the choke and increase back pressure by slowly closing the choke. In this method, the annular pressure loss should be calculated and added to the test pressure results. Testing to an equivalent mud weight: 95

97 1) This test is used primarily on development wells where the maximum mud weight that will be used to drill the next interval is known. 2) Determine the equivalent test mud weight, ppg, Two methods are normally used. Method 1: Add a value to the maximum mud weight that is needed to drill the interval. Example: Maximum mud weight necessary to drill the next interval = 11.5 ppg plus safety factor = 1.0 ppg Equivalent test mud weight, ppg = (maximum mud weight, ppg) + (safety factor, ppg) Equivalent test mud weight Equivalent test mud weight = 11.5 ppg ppg = 12.5 ppg Method 2: Subtract a value from the estimated fracture gradient for the depth of the casing shoe. Equivalent test mud weight = (estimated fracture gradient, ppg ) (safety factor) Example: Estimated formation fracture gradient = 14.2 ppg. Safety factor = 1.0 ppg Equivalent test mud weight = 14.2 ppg 1.0 ppg Determine surface pressure to be used: Surface pressure, psi = (equiv. Test mud wt, ) x x (casing seat, TVD ft) (mud wt, ppg in use, ppg) Example: Mud weight = 9.2 ppg Casing shoe TVD = 4000 ft Equivalent test mud weight = 13.2 ppg Solution: Surface pressure = ( ) x x 4000 ft Surface pressure = 832 psi Testing to leak-off test: 1) This test is used primarily on wildcat or exploratory wells or where the actual fracture is not known. 2) Determine the estimated fracture gradient from a Fracture Gradient Chart. 3) Determine the estimated leak-off pressure. Estimated leak-off pressure = (estimated fracture mud wt ) x x (casing shoe) (gradient in use, ppg) ( TVD, ft ) Example: Mud weight = 9.6 ppg Casing shoe TVD = 4000 ft 96

98 Estimated fracture gradient = 14.4 ppg Solution: Estimated leak-off pressure = ( ) x x 4000 ft Estimated leak-off pressure = 4.8 x x 4000 Estimated leak-off pressure = 998 psi Maximum Allowable Mud Weight From Leak-off Test Data Max allowable = (leak off pressure, psi) (casing shoe) + (mud wt in use, ppg) mud weight, ppg ( TVD, ft ) Example: Determine the maximum allowable mud weight, ppg, using the following data: Leak-off pressure = 1040 psi Casing shoe TVD = 4000 ft Mud weight in use = 10.0 ppg Max allowable mud weight, ppg = ~ Max allowable mud weight, ppg = 15.0 ppg Maximum Allowable Shut-in Casing Pressure (MASLCP) also called maximum allowable shut-in annular pressure (MASP): MASICP = (maximum allowable mud wt in use, ppg) x x (casing shoe TVD, ft) (mud wt, ppg ) Example: Determine the maximum allowable shut-in casing pressure using the following data: Maximum allowable mud weight = 15.0 ppg Mud weight in use = 12.2 ppg Casing shoe TVD = 4000 ft MASICP = ( ) x x 4000 ft MASICP = 582 psi Kick Tolerance Factor (KTF) KTF = Casing shoe TVD, ft) x (maximum allowable mud wt, ppg mud wt in use, ppg) well depth Example: Determine the kick tolerance factor (KTF) using the following data: Mud weight in use = 10.0 ppg Casing shoe TVD = 4000 ft Well depth TVD = 10,000 ft Maximum allowable mud weight (from leak-off test data) = 14.2 ppg 97

99 KTF = (4000 ft 10,000 ft) x (14.2 ppg 10.0 ppg) KTF = 1.68 ppg Maximum Surface Pressure From Kick Tolerance Data Maximum surface pressure = kick tolerance factor, ppg x x TYD, ft Example: Determine the maximum surface pressure, psi, using the following data: Maximum surface pressure = 1.68 ppg x x 10,000 ft Maximum surface pressure = 874 psi Maximum Formation Pressure (FP) That Can be Controlled When Shutting-in a Well Maximum FP, psi = (kick tolerance factor, ppg + mud wt in use, ppg) x x TYD, ft Example: Determine the maximum formation pressure (FP) that can be controlled when shutting-in a well using the following data: Data: Kick tolerance factor = 1.68 ppg Mud weight = 10.0 ppg True vertical depth = 10,000 ft Maximum FP, psi = (1.68 ppg ppg) x x 10,000 ft Maximum FP = 6074 psi Maximum Influx Height Possible to Equal Maximum Allowable Shut-in Casing Pressure (MASICP) Influx height = MASICP, psi (gradient of mud wt in use, psi/ft influx gradient, psi/ft) Example: Determine the influx height, ft, necessary to equal the maximum allowable shutin casing pressure (MASICP) using the following data: Data: Maximum allowable shut-in casing pressure = 874 psi Mud gradient (10.0 ppg x 0.052) = 0.52 psi/ft Gradient of influx = 0.12 psi/ft Influx height = 874 psi (0.52 psi/ft 0.12 psi/fl) Influx height = 2185 ft 98

100 Maximum Influx, Barrels to Equal Maximum Allowable Shut-in Casing Pressure (MASICP) Example: Maximum influx height to equal MASICP (from above example) = 2185 ft Annular capacity drill collars/open hole (12-1/4 in. x 8.0 in.) = bbl/ft Annular capacity drill pipe/open hole (12-1/4 in. x 5.0 in.) = bbl/ft Drill collar length = 500 ft Step 1 Determine the number of barrels opposite drill collars: Barrels = bbl/ft x 500 ft Barrels = 41.8 Step 2 Determine the number of barrels opposite drill pipe: Influx height, ft, opposite drill pipe: ft = 2185 ft 500 ft ft = 1685 Barrels opposite drill pipe: Barrels = 1685 ft x bbl/ft Barrels = Step 3 Determine maximum influx, bbl, to equal maximum allowable shut-in casing pressure: Maximum influx = 41.8 bbl bbl Maximum influx = bbl Adjusting Maximum Allowable Shut-in Casing Pressure For an Increase in Mud Weight MASICP = P L [D x (mud wt 2 mud wt 1 )] where MASICP = maximum allowable shut-in casing (annulus) pressure, psi P L = leak-off pressure, psi D = true vertical depth to casing shoe, ft Mud wt 2 = new mud wt, ppg Mud wt 1 = original mud wt, ppg Example: Leak-off pressure at casing setting depth (TVD) of 4000 ft was 1040 psi with 10.0 ppg in use. Determine the maximum allowable shut-in casing pressure with a mud weight of 12.5 ppg: MASICP = 1040 psi [4000 x ( ) 0.052] MASICP = 1040 psi 520 MASICP = 520 psi 99

101 3. Kick Analysis Formation Pressure (FP) With the Well Shut-in on a Kick FP, psi = SIDPP, psi + (mud wt, ppg x x TVD, ft) Example: Determine the formation pressure using the following data: Shut-in drill pipe pressure = 500 psi True vertical depth = 10,000 ft Mud weight in drill pipe = 9.6 ppg FP, psi = 500 psi + (9.6 ppg x x 10,000 ft) FP, psi = 500 psi psi FP = 5492 psi Bottom hole Pressure (BHP) With the Well Shut-in on a Kick BHP, psi = SIDPP, psi + (mud wt, ppg x x TVD, ft) Example: Determine the bottom hole pressure (BHP) with the well shut-in on a kick: Shut-in drill pipe pressure = 500 psi Mud weight in drill pipe = 9.6 ppg True vertical depth = 10,000 ft BHP, psi = 500 psi + (9.6 ppg x x 10,000 ft) BHP, psi = 500 psi psi BHP = 5492 psi Shut-in Drill Pipe Pressure (SIDPP) SIDPP, psi = formation pressure, psi (mud wt, ppg x x TVD, ft) Example: Determine the shut-in drill pipe pressure using the following data: Formation pressure = 12,480 psi Mud weight in drill pipe = ppg True vertical depth = 15,000 ft SIDPP, psi = 12,480 psi (15.0 ppg x x 15,000 ft) SIDPP, psi = 12,480 psi 11,700 psi SIDPP = 780 psi 100

102 Shut-in Casing Pressure (SICP) SICP = (formation pressure, psi) (HP of mud in annulus, psi + HP of influx in annulus, psi) Example: Determine the shut-in casing pressure using the following data: Formation pressure = 12,480 psi Mud weight in annulus = 15.0 ppg Feet of mud in annulus = 14,600 ft Influx gradient = 0.12 psi/ft Feet of influx in annulus = 400 ft SICP, psi = 12,480 [(15.0 x x 14,600) + (0.12 x 400)] SICP, psi = 12,480 11, SICP = 1044 psi Height, Fl, of Influx Height of influx, ft = pit gain, bbl annular capacity, bbl/ft Example 1: Determine the height, ft, of the influx using the following data: Pit gain = 20 bbl Annular capacity DC/OH = bbl/ft (Dh = 8.5 in. Dp = 6.5) Height of influx, ft = 20 bbl bbl/ft Height of influx = 686 ft Example 2: Determine the height, ft, of the influx using the following data: Pit gain = 20 bbl Hole size = 8.5 in. Drill collar OD = 6.5 in. Drill collar length = 450 ft Drill pipe OD = 5.0 in. Determine annular capacity, bbl/ft, for DC/OH: Annular capacity, bbl/ft = Annular capacity = bbl/ft Determine the number of barrels opposite the drill collars: Barrels = length of collars x annular capacity Barrels = 450 ft x bbl/ft Barrels = 13.1 Determine annular capacity, bbl/ft, opposite drill pipe: Annular capacity, bbl/ft =

103 Annular capacity = bbl/ft Determine barrels of influx opposite drill pipe: Barrels = pit gain, bbl barrels opposite drill collars Barrels = 20 bbl 13.1 bbl Barrels = 6.9 Determine height of influx opposite drill pipe: Height, ft = 6.9 bbl -: bbl/ft Height = 150 ft Determine the total height of the influx: Height, ft = 450 ft ft Height = 600 ft Estimated Type of Influx Influx weight, ppg = mud wt, ppg ((SICP SIDPP) : height of influx, ft x 0.052) then: 1 3 ppg = gas kick 4 6 ppg = oil kick or combination 7 9 ppg = saltwater kick Example: Determine the type of the influx using the following data: Shut-in casing pressure = 1044 psi Height of influx = 400 ft Shut-in drill pipe pressure = 780 psi Mud weight = 15.0 ppg Influx weight, ppg = 15.0 ppg (( ) : 400 x 0.052) Influx weight, ppg = 15.0 ppg Influx weight = 2.31 ppg Therefore, the influx is probably gas. Gas Migration in a Shut-in Well Estimating the rate of gas migration, ft/hr: ( 0.37)(mud wt. ppg) Vg = I 2e Vg = rate of gas migration, ft/hr Example: Determine the estimated rate of gas migration using a mud weight of 11.0 ppg: Vg = 12e ( 0.37)(11.0 ppg) Vg = 12e ( 4.07) Vg = ft/sec Vg = ft/sec x 60 sec/min 102

104 Vg = 12.3 ft/min x 60 min/hr Vg = 738 ft/hr Determining the actual rate of gas migration after a well has been shut-in on a kick: Rate of gas migration, ft/hr = increase in casing pressure, psi/hr pressure gradient of mud weight in use, psi/ft Example: Determine the rate of gas migration with the following data: Stabilised shut-in casing pressure = 500 psi SICP after one hour = 700 psi Pressure gradient for 12.0 ppg mud = psi/ft Mud weight = 12.0 ppg Rate of gas migration, ft/hr = 200 psi/hr psi/ft Rate of gas migration = ft/hr Hydrostatic Pressure Decrease at TD Caused by Gas Cut Mud Method 1: HP decrease, psi = 100 (weight of uncut mud, ppg weight of gas cut mud, ppg) weight of gas cut mud, ppg Example: Determine the hydrostatic pressure decrease mud using the following data: Weight of uncut mud = 18.0 ppg Weight of gas cut mud = 9.0 ppg HP decrease, psi = 100 x (18.0 ppg 9.0 ppg) 9.0 ppg HP Decrease Method 2: = 100 psi P = (MG C) V where P = reduction in bottomhole pressure, psi MG = mud gradient, psi/ft C = annular volume, bbl/ft V = pit gain, bbl Example: MG = psi/ft C = bbl/ft (Dh = 8.5 in.; Dp = 5.0 in.) V = 20 bbl Solution: P = (0.624 psi/ft bbl/ft) 20 P = x 20 P = psi Maximum Surface Pressure From a Gas Kick in a Water Base Mud. MSPgk = 0.2 P x V x KWM C where MSPgk = maximum surface pressure resulting from a gas kick in a water base mud P = formation pressure, psi V = pit gain, bbl 103

105 KWM = kill weight mud, ppg C = annular capacity, bbl/ft Example: P = 12,480 psi V = 20 bbl KWM = 16.0 ppg C = bbl/ft (Dh = 8.5 in. x Dp = 4.5 in.). Solution: MSPgk = ,480 x 20 x MSPgk = MSPgk = 0.2 x MSPgk = 1779 psi Maximum Pit Gain From Gas Kick in a Water Base Mud. MPGgk = 4 P x V x C KWM where MPGgk = maximum pit gain resulting from a gas kick in a water base mud P = formation pressure, psi V = original pit gain, bbl C = annular capacity, bbl/ft KWM = kill weight mud, ppg Example: P = 12,480 psi V = 20 bbl C = bbl/ft (8.5 in. x 4.5 in.). Solution: MPGgk = 4 12,480 x 20 x MPGgk = MPGgk = 4 x MPGgk = bbl Maximum Pressures When Circulating Out a Kick (Moore Equations) The following equations will be used: 1. Determine formation pressure, psi: Pb = SIDP + (mud wt, ppg x x TVD, ft) 2. Determine the height of the influx, ft: hi = pit gain, bbl annular capacity, bbl/ft 3. Determine pressure exerted by the influx, psi: Pi = Pb [Pm (D X) + SICP] 4. Determine gradient of influx, psi/ft: Ci = Pi hi 5. Determine Temperature, R, at depth of interest: Tdi = 70 F + (0.012 F/ft. x Di) Determine A for unweighted mud: A = Pb [Pm (D X) Pi] 7. Determine pressure at depth of interest: Pdi = A + (A 2 + pm Pb Zdi T Rdi hi) 1/2 104

106 2 4 Zb Tb 8. Determine kill weight mud, ppg: KWM, ppg = SIDPP TVD, ft + 0MW, ppg 9. Determine gradient of kill weight mud, psi/ft: pkwm = KWM, ppg x Determine FEET that drill string volume will occupy in the annulus: Di = drill string vol, bbl annular capacity, bbl/ft 11. Determine A for weighted mud: A = Pb [pm (D X) Pi] + [Di (pkwm pm)} Example: Assumed conditions: Well depth = 10,000 ft Hole size = 8.5 in. Surface casing = 9-5/ ft Casing ID = in. Fracture 2500 ft = 0.73 psi/ft (14.04 ppg) Casing ID capacity = bbl/ft Drill pipe = 4.5 in lb/ft Drill collar OD = 6-1/4 in. Drill collar OD length = 625 ft Mud weight = 9.6 ppg Mud volumes: 8-1/2 in. hole = 0.07 bbl/ft in. casing x 4-1/2 in. drill pipe = bbl/ft Drill pipe capacity = bbl/ft 8-1/2 in. hole x 6-1/4 in. drill collars = bbl/ft Drill collar capacity = bbl/ft 8-1/2 in. hole x 4-1/2 in. drill pipe = 0.05 bbl/ft Super compressibility factor (Z) = 1.0 The well kicks and the following information is recorded SIDP = 260 psi SICP = 500 psi pit gain = 20 bbl Determine the following: Maximum pressure at shoe with drillers method Maximum pressure at surface with drillers method Maximum pressure at shoe with wait and weight method Maximum pressure at surface with wait and weight method Determine maximum pressure at shoe with drillers method: 1. Determine formation pressure: Pb = 260 psi + (9.6 ppg x x 10,000 ft) Pb = 5252 psi 2. Determine height of influx at TD: hi = 20 bbl bbl/ft hi = 625 ft 3. Determine pressure exerted by influx at TD: Pi = 5252 psi [ psi/ft (10, ) + 500] 105

107 Pi = 5252 psi [4680 psi + 500] Pi = 5252 psi 5180 psi Pi = 72 psi 4. Determine gradient of influx at TD: Ci = 72 psi 625 ft Ci = psi/ft 5. Determine height and pressure of influx around drill pipe: h = 20 bbl 0.05 bbl/ft h = 400 ft Pi = psi/ft x 400 ft Pi = 46 psi 6. Determine T R at TD and at shoe: T 10,000 ft = 70 + (0.012 x 10,000) = T 10,000ft = 650 T 2500 ft = 70 + (0.012 x 2500) = T R@ 2500ft = Determine A: A = 5252 psi [ (10, ) + 46] A = 5252 psi ( ) A = 1462 psi 8. Determine maximum pressure at shoe with drillers method: P 2500 = [ (0.4992)(5252)(1)(560)(400)] 1/2 2 4 (1) (650) = ( )12 = P 2500 = 1930 psi Determine maximum pressure at surface with drillers method: 1. Determine A: A = 5252 [ (10,000) + 46] A = 5252 ( ) A = 214 psi 2. Determine maximum pressure at surface with drillers method: Ps = [ (0.4992)(5252)(1)(530)(400)] 1/

108 = ( ) 1/2 = Ps = 1038 psi Determine maximum pressure at shoe with wait and weight method: 1. Determine kill weight mud: KWM, ppg = 260 psi ,000 ft ppg KWM, ppg = 10.1 ppg 2. Determine gradient (pm), psi/ft for KWM: pm = 10.1 ppg x pm = psi/ft 3. Determine internal volume of drill string: Drill pipe vol = bbl/ft x 9375 ft = bbl Drill collar vol = bbl/ft x 625 ft = bbl Total drill string volume = bbl 4. Determine FEET drill string volume occupies in annulus: Di = bbl 0.05 bbl/ft Di = Determine A: A = 5252 [ (10, ) 46) + ( ( )] A = 5252 ( ) A = Determine maximum pressure at shoe with wait and weight method: P 2500 = [ (0.5252)(5252)(1)(560)(400) ] 1/2 2 4 (1) (650) = ( ) 1/2 = = 1851 psi Determine maximum pressure at surface with wait and weight method: 1. Determine A: A = 5252 [0.5252(10,000) 46] + [2712.5( )] A = 5252 ( ) A = Determine maximum pressure at surface with wait and weight method: 107

109 Ps = [ (0.5252)(5252)(l)(560)(400) ] 1/2 2 4 (fl(650) Ps = ( ) 1/2 Ps = Ps = 987 psi Nomenclature: A Ci D Di MW Pdi Pi pm psihi Pb pkwm Ps SIDP SICP, T F T R X Zb Zdi = pressure at top of gas bubble, psi = gradient of influx, psi/ft = total depth, ft = feet in annulus occupied by drill string volume = mud weight, ppg = pressure at depth of interest, psi = pressure exerted by influx, psi = pressure gradient of mud weight in use, ppg = height of influx, ft = formation pressure, psi = pressure gradient of kill weight mud, ppg = pressure at surface, psi = shut-in drill pipe pressure, psi = shut-in casing pressure, = temperature, degrees Fahrenheit, at depth of interest = temperature, degrees Rankine, at depth of interest = depth of interest, ft = gas supercompressibility factor TD = gas supercompressibility factor at depth of interest Gas Flow Into the Wellbore Flow rate into the wellbore increases as wellbore depth through a gas sand increases: Q = x md x Dp x L U x ln(re Rw) 1,440 where Q = flow rate, bbl/min md = permeability, millidarcys Dp = pressure differential, psi L = length of section open to wellbore, ft U = viscosity of intruding gas, centipoise Re = radius of drainage, ft Rw = radius of wellbore, ft Example: md = 200 md Dp = 624 psi L =2Oft U = 0.3cp ln(re Rw) = 2,0 Q = x 200 x 624 x x 2.0 x 1440 Q = 20 bbl/min Therefore: If one minute is required to shut-in the well, a pit gain of 20 bbl occurs in addition to the gain incurred while drilling the 20-ft section. 108

110 4. Pressure Analysis Gas Expansion Equations Basic gas laws: P 1 V 1 T 1 = P 2 V, T 2 where P 1 = formation pressure, psi P 2 = hydrostatic pressure at the surface or any depth in the wellbore, psi. V 1 = original pit gain, bbl V 2 = gas volume at surface or at any depth of interest, bbl T 1 = temperature of formation fluid, degrees Rankine ( R = F + 460) T 2 = temperature at surface or at any depth of interest, degrees Rankine Basic gas law plus compressibility factor: P 1 V 1 + T 1 Z 1 = P 2 V 2 + T 2 Z 2 where Z 1 = compressibility factor under pressure in formation, dimensionless Z 2 = compressibility factor at the surface or at any depth of interest, dimensionless Shortened gas expansion equation: P 5 V 1 = P, V 2 where P 1 = formation pressure, psi P 2 = hydrostatic pressure plus atmospheric pressure (14.7 psi), psi V 1 = original pit gain, bbl V 2 = gas volume at surface or at any depth of interest, bbl Hydrostatic Pressure Exerts by Each Barrel of Mud in the Casing With pipe in the wellbore: psi/bbl = x x mud wt, ppg Dh 2 Dp 2 Example: Dh 9-5/8 in, casing 43.5 lb/ft = in. ID Mud weight = 10.5 ppg Dp = 5.0 in. OD psi/bbl = x x 10.5 ppg psi/bbl = x x 10.5 ppg psi/bbl = With no pipe in the wellbore: psi/bbl = x x mud wt ppg ID 2 109

111 Example: Dh 9-5/8 in. casing 43.5 lb/ft = in. ID Mud weight = 10.5 ppg psi/bbl = x x 10.5 ppg psi/bbl = x x 10.5 ppg psi/bbl = 7.33 Surface Pressure During Drill Stem Tests Determine formation pressure: psi = formation pressure equivalent mud wt, ppg x x TVD, ft Determine oil hydrostatic pressure: psi = oil specific gravity x x TVD, ft Determine surface pressure: Surface pressure, psi = formation pressure, psi oil hydrostatic pressure, psi Example: Oil bearing sand at 12,500 ft with a formation pressure equivalent to 13.5 ppg. If the specific gravity of the oil is 0.5, what will be the static surface pressure during a drill stem test? Determine formation pressure, psi: FP, psi = 13.5 ppg x x 12,500 ft FP = 8775 psi Determine oil hydrostatic pressure: psi = (0.5 x 8.33) x x 12,500 ft psi = 2707 Determine surface pressure: Surface pressure, psi = 8775 psi 2707 psi Surface pressure = 6068 psi 110

112 5. Stripping/Snubbing Calculations Breakover Point Between Stripping and Snubbing Example: Use the following data to determine the breakover point: DATA: Mud weight = 12.5 ppg Drill collars (6-1/4 in. 2-13/16 in.) = 83 lb/ft Length of drill collars = 276 ft Drill pipe = 5.0 in. Drill pipe weight = 19.5 lb/ft Shut-in casing pressure = 2400 psi Buoyancy factor = Determine the force, lb, created by wellbore pressure on 6-1/4 in. drill collars: Force, lb = (pipe or collar OD, In) 2 x x (wellbore pressure, psi) Force, lb = x x 2400 psi Force = 73,631 lb Determine the weight, lb, of the drill collars: Wt, lb = drill collar weight, lb/ft x drill collar length, ft x buoyancy factor Wt, lb = 83 lb/ft x 276 ft x Wt, lb = 18,537 lb Additional weight required from drill pipe: Drill pipe weight, lb = force created by wellbore pressure, lb drill collar weight, lb Drill pipe weight, lb = 73,631 lb 18,537 lb Drill pipe weight, lb = 55,094 lb Length of drill pipe required to reach breakover point: Drill pipe = (required drill pipe weight, lb) : (drill pipe weight, lb/ft x factor buoyancy) length, ft Drill pipe length, ft = 55,094 lb : (19.5 lb/ft x ) Drill pipe length, ft = 3492 ft Length of drill string to reach breakover point: Drill string length, ft = drill collar length, ft + drill pipe length, ft Drill string length, ft = 276 ft ft Drill string length = 3768 ft 111

113 Minimum Surface Pressure Before Stripping is Possible Minimum surface = (weight of one stand of collars, lb) : (area of drill collars, sq in.) pressure, psi Example: Drill collars 8.0 in. OD x 3.0 in. ID = 147 lb/ft Length of one stand 92 ft Minimum surface pressure, psi = (147 lb/ft x 92 ft) : (8 2 x ) Minimum surface pressure, psi = 13,524 : sq in. Minimum surface pressure = 269 psi Height Gain From Stripping into Influx Height, ft = L (Cdp + Ddp) Ca where L = length of pipe stripped, ft Cdp = capacity of drill pipe, drill collars, or tubing, bbl/ft Ddp = displacement of drill pipe, drill collars or tubing, bbl/ft Ca = annular capacity, bbl/ft Example: If 300 ft of 5.0 in. drill pipe 19.5 lb/ft is stripped into an influx in a 12-1/4 in. hole, determine the height, ft, gained: DATA: Drill pipe capacity = bbl/ft Length drill pipe stripped = 300 ft Drill pipe displacement = bbl/ft Annular capacity = bbl/ft Solution: Height, ft = 300 ( ) Height = 62.5 ft Casing Pressure Increase From Stripping Into Influx psi = (gain in height, ft) x (gradient of mud, psi/ft gradient of influx, psi/ft) Example: Gain in height = 62.5 ft Gradient of mud (12.5 ppg x 0.052) = 0.65 psi/ft Gradient of influx = 0.12 psi/ft psi = 62.5 ft x ( ) psi = 33 psi Volume of Mud to Bleed to Maintain Constant Bottomhole Pressure with a Gas Bubble Rising 112

114 With pipe in the hole: Vmud = Dp x Ca. gradient of mud, psi/ft where Vmud = volume of mud, bbl, that must be bled to maintain constant bottomhole pressure with a gas bubble rising. Dp = incremental pressure steps that the casing pressure will be allowed to increase. Ca = annular capacity, bbllft Example: Casing pressure increase per step = 100 psi Gradient of mud (13.5 ppg x 0.052) = 0.70 psi/ft Annular capacity (Dh = 12-1/4 in.; Dp = 5.0 in.) = bbl/ft Vmud = 100 psi x bbl/ft psi/ft Vmud = 17.3 bbl With no pipe in hole: Vmud = Dp x Ch. gradient of mud, psi/ft Example: Casing pressure increase per step = 100 psi Gradient of mud (13.5 ppg x 0.052) = psi/ft Hole capacity (12-1/4 in.) = bbl/ft Vmud = 100 psi x bbl/ft psi/ft Vmud = bbl Maximum Allowable Surface Pressure (MASP) Governed by the Formation MASP, psi = (maximum allowable mud wt, in use,) x casing shoe TVD, ft (mud wt, ppg ppg ) Example: Maximum allowable mud weight = 15.0 ppg (from leak-off test data) Mud weight = 12.0 ppg Casing seat TVD = 8000 ft MASP, psi = ( ) x x 8000 MASP = 1248 psi Maximum Allowable Surface Pressure (MASP) Governed by Casing Burst Pressure MASP = (casing burst x safety) (mud wt in mud wt outside) x x casing, shoe (pressure, psi factor) (use, ppg casing, ppg TVD ft Example: Casing 10-3/4 in. 51 lb/ft N-80 Casing burst pressure = 6070 psi 113

115 Casing setting depth = 8000 ft Mud weight in use = 12.0 ppg Mud weight behind casing = 9.4 ppg Casing safety factor = 80% MASP = (6070 x 80%) [( ) x x 8000] MASP = 4856 (2.6 x x 8000) MASP = 3774 psi 6. Subsea Considerations Casing Pressure Decrease when Bringing Well on Choke When bringing the well on choke with a subsea stack, the casing pressure (annulus pressure) must be allowed to decrease by the amount of choke line pressure loss (friction pressure): Reduced casing pressure, psi = (shut-in casing pressure, psi) (choke line pressure loss, psi) Example: Shut-in casing (annulus) pressure (SICP) = 800 psi Choke line pressure loss (CLPL) = 300 psi Reduced casing pressure, psi = 800 psi 300 psi Reduced casing pressure = 500 psi Pressure Chart for Bringing Well on Choke Pressure/stroke relationship is not a straight line effect. While bringing the well on choke, to maintain a constant bottomhole pressure, the following chart should be used: Pressure Chart Strokes Line 1: Reset stroke counter to 0 = 0 Line 2: 1/2 stroke rate = 50 x 0.5 = 25 Line 3: 3/4 stroke rate = 50 x 0.75 = 38 Line 4: 7/8 stroke rate = 50 x = 44 Line 5: Kill rate speed = 50 Pressure Strokes side: Example: kill rate speed = 50 spm Pressure side: Example. Shut-in casing pressure (SICP) = 800 psi Choke line pressure loss (CLPL) = 300 psi Divide choke line pressure loss (CLPL) by 4, because there are 4 steps on the chart: psi/line = (CLPL) 300 psi = 75 psi 4 Pressure Chart Strokes Pressure 114

116 Line 1: Shut-in casing pressure, psi = 800 Line 2: Subtract 75 psi from Line 1 = 725 Line 3: Subtract 75 psi from Line 2 = 650 Line 4: Subtract 75 psi from Line 3 = 575 Line 5: Reduced casing pressure = 500 Maximum Allowable Mud Weight, ppg, Subsea Stack as Derived from Leak-off Test Data Maximum allowable = (leak-off test ) : : (TVD, ft RKB ) + (mud wt in use, ppg) mud weight ppg (pressure, psi) ( to casing shoe) Example: Leak-off test pressure = 800 psi TVD from rotary bushing to casing shoe = 4000 ft Mud in use = 9.2 ppg Maximum allowable mud weight, ppg = : Maximum allowable mud weight = 13.0 ppg Maximum Allowable Shut-in Casing (Annulus) Pressure MASICP = (maximum allowable mud wt in) x x (RKB to casing shoe TVD, ft) (mud wt, ppg use, ppg ) Example: Maximum allowable mud weight = 13.3 ppg Mud weight in use = 11.5 ppg TVD from rotary Kelly bushing to casing shoe = 4000 ft MASICP = (13.3 ppg 11.5 ppg) x x 4000 ft MASICP = 374 Casing Burst Pressure Subsea Stack Step 1 Determine the internal yield pressure of the casing from the Dimensions and Strengths section of cement company s service handbook. Step 2 Correct internal yield pressure for safety factor. Some operators use 80%; some use 75%, and others use70%: Correct internal yield pressure, psi = (internal yield pressure, psi ) x SF Step 3 Determine the hydrostatic pressure of the mud in use: NOTE: The depth is from the rotary Kelly bushing (RKB) to the mud line and includes the air gap plus the depth of seawater. HP, psi = (mud weight in use, ppg) x x (TVD, ft from RKB to mud line) 115

117 Step 4 Determine the hydrostatic pressure exerted by the seawater: HPsw = seawater weight, ppg x x depth of seawater, ft Step 5 Determine casing burst pressure (CBP): CBP x (corrected internal ) (HP of mud in use, psi + HP of seawater, psi) (yield pressure, psi) Example: Determine the casing burst pressure, subsea stack, using the following data: DATA: Mud weight = 10.0 ppg Weight of seawater = 8.7 ppg Air gap = 50 ft Water depth = 1500 ft Correction (safety) factor = 80% Step 1 Determine the internal yield pressure of the casing from the Dimension and Strengths section of a cement company handbook: 9-5/8 casing C-75, 53.5 lb/ft Internal yield pressure = 7430 psi Step 2 Correct internal yield pressure for safety factor: Corrected internal yield pressure = 7430 psi x 0.80 Corrected internal yield pressure = 5944 psi Step 3 Determine the hydrostatic pressure exerted by the mud in use: HP of mud, psi = 10.0 ppg x x (50 ft ft) HP of mud = 806 psi Step 4 Determine the hydrostatic pressure exerted by the seawater: HPsw = 8.7 ppg x x 1500 ft HPsw = 679 psi Step 5 Determine the casing burst pressure: Casing burst pressure, psi = 5944 psi 806 psi psi Casing burst pressure = 5817 psi Calculate Choke Line Pressure Loss (CLPL), Psi CLPL = x MW, ppg x length, ft x GPM 1.86 choke line ID, in Example: Determine the choke line pressure loss (CLPL), psi, using the following data: 116

118 DATA: Mud weight = 14.0 ppg Choke line length = 2000 ft Circulation rate = 225 gpm Choke line ID = 2.5 in. CLPL = x 14.0 ppg x 2000 ft x CLPL = CLPL = psi Velocity, Ft/Mm, Through the Choke Line V, ft/mm = 24.5 x gpm ID, in. 2 Example: Determine the velocity, ft/mm, through the choke line using the following data: Data: Circulation rate = 225 gpm Choke line ID = 2.5 in. V, ft/min = 24.5 x V = 882 ft/min Adjusting Choke Line Pressure Loss for a Higher Mud Weight New CLPL = higher mud wt, ppg x CLPL old mud weight, ppg Example: Use the following data to determine the new estimated choke line pressure loss: Data: Old mud weight = 13.5 ppg New mud weight = 15.0 ppg Old choke line pressure loss = 300 psi New CLPL =15.0 ppg x 300 psi 13.5 ppg New CLPL = psi Minimum Conductor Casing Setting Depth Example: Using the following data, determine the minimum setting depth of the conductor casing below the seabed: Data: Maximum mud weight (to be used while drilling this interval) = 9.0 ppg Water depth = 450 ft Gradient of seawater = psi/ft 117

119 Air gap = 60 ft Formation fracture gradient = 0.68 psi/ft Step 1 Determine formation fracture pressure: psi = (450 x 0.445) + (0.68 x y ) psi = O.68 y Step 2 Determine hydrostatic pressure of mud column: psi = 9.0 ppg x x ( y ) psi = [9.0 x x ( )] + (9.0 x x y ) psi = y Step 3 Minimum conductor casing setting depth: y = y 0.68 y y = y = y = y = ft Therefore, the minimum conductor casing setting depth is ft below the seabed. Maximum Mud Weight with Returns Back to Rig Floor Example: Using the following data, determine the maximum mud weight that can be used with returns back to the rig floor: Data: Depths - Air gap = 75 ft Conductor casing psi/ft set at = 1225 ft RKB Depths - Water depth = 600ft Formation fracture gradient = 0.58 psi/ft Seawater gradient = psi/ft Step 1 Determine total pressure at casing seat: psi = [0.58 ( )] + (0.445 x 600) psi = psi = 586 Step 2 Determine maximum mud weight: Max mud wt = 586 psi ft Max mud wt = 9.2 ppg Reduction in Bottomhole Pressure if Riser is Disconnected 118

120 Example: Use the following data and determine the reduction in bottom-hole pressure if the riser is disconnected: Data: Air gap = 75 ft Water depth = 700 ft Seawater gradient = psi/ft Well depth = 2020 ft RKB Mud weight = 9.0 ppg Step 1 Determine bottomhole pressure: BHP = 9.0 ppg x x 2020 ft BHP = psi Step 2 Determine bottomhole pressure with riser disconnected: BHP = (0.445 x 700) + [9.0 x x ( )] BHP = BHP = psi Step 3 Determine bottomhole pressure reduction: BHP reduction = psi psi BHP reduction = 51.2 psi Bottomhole Pressure When Circulating Out a Kick Example: Use the following data and determine the bottomhole pressure when circulating out a kick: Data: Total depth RKB = 13,500 ft Gas gradient = 0.12 psi/ft Height of gas kick in casing = 1200 ft Kill weight mud = 12.7 ppg Original mud weight = 12.0 ppg Pressure loss in annulus = 75 psi Choke line pressure loss = 220 psi Air gap = 75 ft Annulus (casing) pressure = 631 psi Water depth = 1500 ft Original mud in casing below gas = 5500 ft Step 1 Hydrostatic pressure in choke line: psi = 12.0 ppg x x ( ) psi = Step 2 Hydrostatic pressure exerted by gas influx: psi = 0.12 psi/ft x 1200 ft psi = 144 Step 3 Hydrostatic pressure of original mud below gas influx: psi = 12.0 ppg x x 5500 ft 119

121 psi = 3432 Step 4 Hydrostatic pressure of kill weight mud: psi = 12.7 ppg x x (13, ) psi = 12.7 ppg x x 5225 psi = Step 5 Bottomhole pressure while circulating out a kick: Pressure in choke line Pressure of gas influx Original mud below gas in casing Kill weight mud Annulus (casing) pressure Choke line pressure loss Annular pressure loss = psi = 144 psi = 3432 psi = psi = 630 psi = 200 psi = 75 psi psi 7. Workover Operations NOTE: The following procedures and calculations are more commonly used in workover operations, but at times they are used in drilling operations. Bullheading Bullheading is a term used to describe killing the well by forcing formation fluids back into the formation by pumping kill weight fluid down the tubing and in some cases down the casing. The Bullheading method of killing a well is primarily used in the following situations: a) Tubing in the well with a packer set. No communication exists between tubing and annulus. b) Tubing in the well, influx in the annulus, and for some reason, cannot circulate through the tubing. c) No tubing in the well. Influx in the casing. Bullheading is simplest, fastest, and safest method to use to kill the well. NOTE: Tubing could be well off bottom also. d) In drilling operations, bullheading has been used successfully in areas where hydrogen sulphide is a possibility. 120

122 Example calculations involved in bullheading operations: Using the information given below, the necessary calculations will be performed to kill the well by bullheading. The example calculations will pertain to a above: DATA: Depth of perforations Fracture gradient Formation pressure gradient Tubing hydrostatic pressure (THP) Shut-in tubing pressure Tubing Tubing capacity Tubing internal yield pressure Kill fluid density = 6480 ft = psi/ft = psi/ft = 326 psi = 2000 psi = 2-7/8 in. 6.5 lb/ft = bbl/ft = 7260 psi = 8.4 ppg NOTE: Determine the best pump rate to use. The pump rate must exceed the rate of gas bubble migration up the tubing. The rate of gas bubble migration, ft/hr, in a shut-in well can be determined by the following formula: Rate of gas migration, ft/hr = increase in pressure per/hr, psi completion fluid gradient, psi/ft Solution: Calculate the maximum allowable tubing (surface) pressure (MATP) for formation fracture: a) MATP, initial, with influx in the tubing: MATP, initial = (fracture gradient, psi/ft x depth of perforations, ft) (tubing hydrostatic) (pressure, psi ) MATP, initial = (0.862 psi/ft x 6480 ft) 326 psi MATP, initial = 5586 psi 326 psi MATP, initial = 5260 psi b) MATP, final, with kill fluid in tubing: MATP, final = (fracture gradient, psi/ft x depth of perforations, ft) (tubing hydrostatic) (pressure, psi ) MATP, final = (0.862 x 6480) (8.4 x x 6480) MATP, final = 5586 psi 2830 psi MATP, final = 2756 psi 121

123 Determine tubing capacity: Tubing capacity, bbl = tubing length, ft x tubing capacity, bbl/ft Tubing capacity bbl, = 6480 ft x bbl/ft Tubing capacity = 37.5 bbl Plot these values as shown below: Figure 4-3. Tubing pressure profile. Lubricate and Bleed The lubricate and bleed method involves alternately pumping a kill fluid into the tubing or into the casing if there is no tubing in the well, allowing the kill fluid to fall, then bleeding off a volume of gas until kill fluid reaches the choke. As each volume of kill fluid is pumped into the tubing, the SITP should decrease by a calculated value until the well is eventually killed. This method is often used for two reasons: 1) shut-in pressures approach the rated working pressure of the wellhead or tubing and dynamic pumping pressure may exceed the limits, as in the case of bullheading, and 2) either to completely kill the well or lower the SITP to a value where other kill methods can be safely employed without exceeding rated limits. 122

124 This method can also be applied when the wellbore or perforations are lugged, rendering bullheading useless. In this case, the well can be killed without necessitating the use of tubing or snubbing small diameter tubing. Users should be aware that the lubricate and bleed method is often a very time consuming process, whereas another method may kill the well more quickly. The following is an example of a typical lubricate and bleed kill procedure. Example: A workover is planned for a well where the SITP approaches the working pressure of the wellhead equipment. To minimise the possibility of equipment failure, the lubricate and bleed method will be used to reduce the SITP to a level at which bullheading can be safely conducted. The data below will be used to describe this procedure: TVD = 6500 ft Depth of perforations = 6450 ft SITP = 2830 psi Tubing 6.5 lb/ft-n-80 = 2-7/8 in. Kill fluid density = 9.0 ppg Wellhead working pressure = 3000 psi Tubing internal yield = 10,570 psi Tubing capacity = bbl/ft ( ft/bbl) Calculations: pumped: Calculate the expected pressure reduction for each barrel of kill fluid psi/bbl = tubing capacity, ft/bbl x x kill weight fluid, ppg psi/bbl = ft/bbl x x 9.0 ppg psi/bbl = For each one barrel pumped, the SITP will be reduced by psi. Calculate tubing capacity, bbl, to the perforations: bbl = tubing capacity, bbl/ft x depth to perforations, ft bbl = bbl/ft x 6450 ft bbl = 37.3 bbl Procedure: 1. Rig up all surface equipment including pumps and gas flare lines. 2. Record SITP and SICP. 3. Open the choke to allow gas to escape from the well and momentarily reduce the SITP. 4. Close the choke and pump in 9.0 ppg brine until the tubing pressure reaches 2830 psi. 5. Wait for a period of time to allow the brine to fall in the tubing. This period will range from 1/4 to 1 hour depending on gas density, pressure, and tubing size. 6. Open the choke and bleed gas until 9.0 brine begins to escape. 7. Close the choke and pump in 9.0 ppg brine water. 8. Continue the process until a low level, safe working pressure is attained. 123

125 A certain amount of time is required for the kill fluid to fall down the tubing after the pumping stops. The actual waiting time is not to allow fluid to fall, but rather, for gas to migrate up through the kill fluid. Gas migrates at rates of 1000 to 2000 ft/hr. Therefore considerable time is required for fluid to fall or migrate to 6500 ft. Therefore, after pumping, it is important to wait several minutes before bleeding gas to prevent bleeding off kill fluid through the choke. References Adams, Neal, Well Control Problems and Solutions, PennWell Publishing Company, Tulsa, OK, Adams, Neal, Workover Well Control, PennWell Publishing Company, Tulsa, OK, Goldsmith, Riley, Why Gas Cut Mud Is Not Always a Serious Problem, World Oil, Oct Grayson, Richard and Fred S. Mueller, Pressure Drop Calculations For a Deviated Wellbore, Well Control Trainers Roundtable, April Petex, Practical Well Control; Petroleum Extension Service University of Texas, Austin, Tx, Well Control Manual, Baroid Division, N.L. Petroleum Services, Houston, Texas. Various Well Control Schools/Courses/Manuals NL Baroid, Houston, Texas USL Petroleum Training Service, Lafayette, La. Prentice & Records Enterprises, Inc., Lafayette, La. Milchem Well Control, Houston, Texas Petroleum Extension Service, Univ. of Texas, Houston, Texas Aberdeen Well Control School, Gene Wilson, Aberdeen, Scotland 124

126 CHAPTER FIVE ENGINEERING CALCULATIONS 125

127 1. Bit Nozzle Selection Optimised Hydraulics These series of formulas will determine the correct jet sizes when optimising for jet impact or hydraulic horsepower and optimum flow rate for two or three nozzles. 1. Nozzle area, sq in.: Nozzle area, sq in. = N1 2 + N2 2 + N Bit nozzle pressure loss, psi (Pb): Pb = gpm 2 x MW, ppg x nozzle area, sq in Total pressure losses except bit nozzle pressure loss, psi (Pc): Pc 1 & Pc 2 = circulating pressure, psi bit nozzle pressure Loss. 4. Determine slope of line M: M = log (Pc 1 Pc 2 ) log (Q 1 Q 2 ) 5. Optimum pressure losses (Popt) a) For impact force: Popt = 2 x Pmax M+2 b) For hydraulic horsepower: Popt = 1 x Pmax M For optimum flow rate (Qopt): a) For impact force: Qopt, gpm = (Popt ) 1 M x Q1 Pmax b) For hydraulic horsepower: Qopt, gpm = (Popt ) 1 M x Q1 Pmax 7. To determine pressure at the bit (Pb): Pb = Pmax Popt 8. To determine nozzle area, sq in.: Nozzle area, sq in. = Qopt 2 x MW, ppg. 126

128 10858 x Pmax 9. To determine nozzles, 32nd in. for three nozzles:. Nozzles = Nozzle area, sq in. x 32 3 x To determine nozzles, 32nd in. for two nozzles:. Nozzles = Nozzle area, sq in. x 32 2 x Example: Optimise bit hydraulics on a well with the following: Select the proper jet sizes for impact force and hydraulic horsepower for two jets and three jets: DATA: Mud weight = 13.0 ppg Maximum surface pressure = 3000 psi Pump rate 1 = 420 gpm Pump pressure 1 = 3000 psi Pump rate 2 = 275 gpm Pump pressure 2 = 1300 psi Jet sizes = Nozzle area, sq in.: Nozzle area, sq in. = Nozzle area, sq in. = Bit nozzle pressure loss, psi (Pb): Pb, = 4202 x x Pb, = 478 psi Pb 2 = x x Pb 2 = 205 psi 3. Total pressure losses except bit nozzle pressure loss (Pc), psi: Pc, = 3000 psi 478 psi Pc, = 2522 psi Pc 2 = 1300 psi 205 psi Pc 2 = 1095 psi 127

129 4. Determine slope of line (M): M = log ( ) log ( ) M = M = Determine optimum pressure losses, psi (Popt): a) For impact force: Popt = 2 x Popt = 1511 psi b) For hydraulic horsepower: Popt = 1 x Popt = 1010 psi 6. Determine optimum flow rate (Qopt): a) For impact force: Qopt, gpm = (1511) x Qopt = 297 gpm b) For hydraulic horsepower: Qopt, gpm = (1010) x Qopt = 242 gpm 7. Determine pressure losses at the bit (Pb): a) For impact force: Pb = 3000 psi 1511 psi Pb = 1489 psi b) For hydraulic horsepower: Pb = 3000 psi 1010 psi Pb = 1990 psi 8. Determine nozzle area, sq in.: a) For impact force: Nozzles area, sq. in. = x x Nozzles area, sq. in. = Nozzle area, = sq. in.. b) For hydraulic horsepower: Nozzles area, sq. in. = x x

130 9. Determine nozzle size, 32nd in.: Nozzles area, sq. in. = Nozzle area, = sq. in.. a) For impact force: Nozzles = x 32 3 x Nozzles = b) For hydraulic horsepower: Nozzles = x 32 3 x Nozzles = 9.03 NOTE: Usually the nozzle size will have a decimal fraction. The fraction times 3 will determine how many nozzles should be larger than that calculated. a) For impact force: 0.76 x 3 = 2.28 rounded to 2 so: 1 jet = 10/32nds 2 jets = 11/32nds b) For hydraulic horsepower: 0.03 x 3 = 0.09 rounded to 0 so: 3 jets = 9/32 nd in. 10. Determine nozzles, 32nd in. for two nozzles:. a) For impact force: Nozzles = x 32 2 x Nozzles = sq in.. b) For hydraulic horsepower: Nozzles = x 32 2 x Nozzles = sq in. 2. Hydraulics Analysis This sequence of calculations is designed to quickly and accurately analyse various parameters of existing bit hydraulics. 1. Annular velocity, ft/mm (AV): AV = 24.5 x Q Dh 2 Dp 2 2. Jet nozzle pressure loss, psi (Pb): Pb = x Q 2 x MW [(N) 2 + (N 2 ) 2 + (N 3 ) 2 ] 2 3. System hydraulic horsepower available (Sys HHP): SysHHP = surface, psi x Q 129

131 Hydraulic horsepower at bit (HHPb): HHPb = Q x Pb Hydraulic horsepower per square inch of bit diameter: HHPb/sq in. = HHPb x 1.27 bit size 2 6. Percent pressure loss at bit (% psib): %psib = Pb x 100 surface, psi 7. Jet velocity, ft/sec (Vn): Vn = x Q (N 1 ) 2 + (N 2 ) 2 + (N 3 ) 2 8. Impact force, lb, at bit (IF): IF = (MW) (Vn) (Q) Impact force per square inch of bit area (IF/sq in.): IF/sq in. = IF x 1.27 bit size 2 Nomenclature: AV = annular velocity, ft/mm Q = circulation rate, gpm Dh = hole diameter, in. Dp = pipe or collar OD, in. MW = mud weight, ppg N 1 N 2 N 3 = jet nozzle sizes, 32nd in. Pb = bit nozzle pressure loss, psi HHP = hydraulic horsepower at bit Vn = jet velocity, ft/sec IF = impact force, lb IF/sq in. = impact force lb/sq in of bit diameter Example: Mud weight = 12.0 ppg Circulation rate = 520 gpm Nozzle size 1 = 12-32nd/in. Surface pressure = 3000 psi Nozzle size 2 = 12-32nd/in. Hole size = 12-1/4 in. Nozzle size 3 = 12-32nd/in. Drill pipe OD = 5.0 in. 1. Annular velocity, ft/mm: AV = 24.5 x AV = AV = 102 ft/mm 2. Jet nozzle pressure loss: Pb = x 5202 x 12.0 ( ) 2 Pb = 2721 psi 3. System hydraulic horsepower available: Sys HHP = 3000 x Sys HHP =

132 4. Hydraulic horsepower at bit: HHPb = 2721 x HHPb = Hydraulic horsepower per square inch of bit area: HHP/sq in. = 826 x HHP/sq in. = Percent pressure loss at bit: % psib = 2721 x % psib = Jet velocity, ft/see: Vn = x Vn = Vn = 502 ft/sec 8. Impact force, lb: IF = 12.0 x 502 x IF = 1623 lb 9. Impact force per square inch of bit area: IF/sq in. = 1623 x IF/sq in. = Critical Annular Velocity and Critical Flow Rate 1. Determine n: n = 3.32 log φ600 φ Determine K: K= φ n 3. Determine X: X = (Kp) (n) (Dh Dp) n MW 4. Determine critical annular velocity: AVc = (X) 1 2 n 5. Determine critical flow rate: GPMc = AVc (Dh 2 - Dp 2 ) 131

133 24.5 Nomenclature: n = dimensionless Dh = hole diameter, in. K = dimensionless Dp = pipe or collar OD, in. X = dimensionless MW = mud weight, ppg φ600 = 600 viscometer dial reading Avc = critical annular velocity, ft/mm φ300 = 300 viscometer dial reading GPMc = critical flow rate, gpm Example: Mud weight = 14.0 ppg Hole diameter = 8.5 in. φ600 = 64 Pipe OD = 7.0 in. φ300 = Determine n: n = 3.32 log n = Determine K: K = K = Determine X: X = (0.2684) (079) x 14.0 X = X = (2 0.79) 4. Determine critical annular velocity: AVc = (1035) AVc = (1035) AVc = 310 ft/mm 5. Determine critical flow rate: GPMc = 310 ( ) 24.5 GPMc = 294 gpm 4. d Exponent The d exponent is derived from the general drilling equation: R N = a (W d D) where R = penetration rate N = rotary speed, rpm d = exponent in general drilling equation, dimensionless a = a constant, dimensionless 132

134 W = weight on bit, lb d exponent equation: d = log (R 60N) log (12W 1000D) where d = d exponent, dimensionless R = penetration rate, ft/hr N = rotary speed, rpm W = weight on bit, 1,000 lb D = bit size, in. Example: R = 30 ft/hr N = 120 rpm W = 35,000 lb D = 8.5 in. Solution: d = log [30 (60 x 120)] log [(12 x 35) (1000 x 8.5)] d = log ( ) log ( ) d = log log d = d = 1.82 Corrected d exponent: The d exponent is influenced by mud weight variations, so modifications have to be made to correct for changes in mud weight: d c = d (MW 1 MW 2 ) where dc = corrected d exponent MW 1 = normal mud weight 9.0 ppg MW 2 = actual mud weight, ppg Example: d = 1.64 MW 1 = 9.0 ppg MW 2 = 12.7 ppg Solution: d c = 1.64 ( ) d c = 1.64 x 0.71 d c = Cuttings Slip Velocity These calculations give the slip velocity of a cutting of a specific size and weight in a given fluid. The annular velocity and the cutting net rise velocity are also calculated. Method 1 Annular velocity, ft/mm: AV = 24.5 x Q Dh 2 Dp 2 Cuttings slip velocity, ft/mm: Vs = 0.45( PV ) [ 36,800 (PV (MW)(Dp)) 2 x (Dp)((DenP MW) l) ] (MW)(Dp). where Vs = slip velocity, ft/min PV = plastic viscosity, cps 133

135 MW = mud weight, ppg DenP = density of particle, ppg Dp = diameter of particle, in. DATA: Mud weight = 11.0 ppg Plastic viscosity = 13 cps Diameter of particle = 0.25 in. Density of particle = 22 ppg Flow rate = 520 gpm Diameter of hole = 12-1/4 in. Drill pipe OD = 5.0 in. Annular velocity, ft/mm: AV = 24.5 x AV = 102 ft/min Cuttings slip velocity, ft/mm: Vs = 0.45( 13 ) [ 36,800 (13 (11 x 0.25)) 2 x 0.25((22 11) l) ] (11 x 0.25). Vs = 0.45[ [ 36,800 [4.727] 2 x 0.25 x ]. Vs = ( 4l ) Vs = x Vs = ft/mm. Cuttings net rise velocity: Annular velocity = 102 ft/min Cuttings slip velocity = 41 ft/min Cuttings net rise velocity = 61 ft/min Method 2 1. Determine n: n = 3.32 log φ600 φ Determine K: K= φ n 3. Determine annular velocity, ft/mm: v = 24.5 x Q Dh 2 Dp 2 4. Determine viscosity (u): µ = ( 2.4v x 2n + 1) n x (200K (Dh Dp) Dh Dp 3n v 5. Slip velocity (Vs), ft/mm: Vs = (DensP MW) x 175 x DiaP MW x µ

136 Nomenclature: n = dimensionless Q = circulation rate, gpm K = dimensionless Dh = hole diameter, in. φ600 = 600 viscometer dial reading DensP = cutting density, ppg φ300 = 300 viscometer dial reading DiaP = cutting diameter, in. Dp = pipe or collar OD, in. v = annular velocity, ft/min µ = mud viscosity, cps Example: Using the data listed below, determine the annular velocity, cuttings slip velocity, and the cutting net rise velocity: DATA: Mud weight = 11.0 ppg Plastic viscosity = 13 cps Yield point = 10 lb/100 sq. ft Diameter of particle = 0.25 in. Hole diameter = in. Density of particle = 22.0 ppg Drill pipe OD = 5.0 in. Circulation rate = 520 gpm 1. Determine n: n = 3.32 log n = Determine K: K= K = Determine annular velocity, ft/mm: v = 24.5 x Determine mud viscosity, cps: v = 12, v = 102 ft/min µ = (2.4 x 102 x 2( ) + 1) x (200 x x ( ) x µ = (2448 x 2.292) x µ = (33.76 x ) x 5.82 µ = x 5.82 µ = 63 cps 5. Determine slip velocity (Vs), ft/mm: Vs = (22 11) x 175 x x Vs = 4.95 x 175 x x

137 Vs = Vs = ft/min 6. Determine cuttings net rise velocity, ft/mm: Annular velocity = 102 ft/mm Cuttings slip velocity = ft/mm Cuttings net rise velocity = ft/mm 6. Surge and Swab Pressures Method 1 1. Determine n: n = 3.32 log φ600 φ Determine K: K= φ n 3. Determine velocity, ft/mm: For plugged flow: v = [ Dp 2 ] Vp Dh 2 Dp 2 For open pipe: v = [ Dp 2 Di 2 ] Vp Dh 2 Dp 2 + Di 2 4. Maximum pipe velocity: Vm = 1.5 x v 5. Determine pressure losses: Ps = (2.4 Vm x 2n + 1) n x KL. Dh Dp 3n 300 (Dh Dp) Nomenclature: n = dimensionless Di = drill pipe or drill collar ID, in. K = dimensionless Dh = hole diameter, in. φ600 = 600 viscometer dial reading Dp = drill pipe or drill collar OD, in φ300 = 300 viscometer dial reading Ps = pressure loss, psi v = fluid velocity, ft/min Vp = pipe velocity, ft/min Vm = maximum pipe velocity, ft/mm L = pipe length, ft 136

138 Example 1: Determine surge pressure for plugged pipe: Data: Well depth = 15,000 ft Drill pipe OD = 4-1/2 in. Hole size = 7-7/8 in. Drill pipe ID = 3.82 in. Drill collar length = 700 ft Mud weight = 15.0 ppg Average pipe running speed = 270 ft/mm Drill collar = 6-1/4 OD x 2-3/4 ID Viscometer readings: φ600 = 140 φ300 = Determine n: n = 3.32 log n = Determine K: K= K= Determine velocity, ft/mm: v = [ ] v = ( )270 v = 252 ft/min 4. Determine maximum pipe velocity, ft/min: Vm = 1.5 x 252 Vm = 378 ft/min 5. Determine pressure losses, psi: Ps =[ 2.4 x 378 x 2(0.8069) + 1] x (0.522)(14300) (0.8069) 300 ( ) Ps = (268.8 x ) x Ps = x 7.37 Ps = 716 psi surge pressure Therefore, this pressure is added to the hydrostatic pressure of the mud in the wellbore. If, however, the swab pressure is desired, this pressure would be subtracted from the hydrostatic pressure. Example 2: Determine surge pressure for open pipe: 1. Determine velocity, ft/mm: : v = [ ] v = ( )

139 v = ( )270 v = 149 ft/mm 2. Maximum pipe velocity, ft/mm: Vm = 149 x 1.5 Vm = 224 ft/mm 3. Pressure loss, psi: Ps = [ 2.4 x 224 x 2(0.8069) + 1 ] x (0.522)(14300) (0.8069) 300( ) Ps = ( x ) x Ps = x 7.37 Ps = 469 psi surge pressure Therefore, this pressure would be added to the hydrostatic pressure of the mud in the wellbore. If, however, the swab pressure is desired, this pressure would be subtracted from the hydrostatic pressure of the mud in the wellbore. Method 2 Surge and swab pressures Assume: 1) Plugged pipe 2) Laminar flow around drill pipe 3) Turbulent flow around drill collars These calculations outline the procedure and calculations necessary to determine the increase or decrease in equivalent mud weight (bottomhole pressure) due to pressure surges caused by pulling or running pipe. These calculations assume that the end of the pipe is plugged (as in running casing with a float shoe or drill pipe with bit and jet nozzles in place), not open ended. A. Surge pressure around drill pipe: 1. Estimated annular fluid velocity (v) around drill pipe: v = [ Dp 2 ] Vp Dh 2 Dp 2 2. Maximum pipe velocity (Vm): Vm = v x Determine n: n = 3.32 log φ600 φ Determine K: K= φ n 138

140 5. Calculate the shear rate (Ym) of the mud moving around the pipe: Ym = 2.4 x Vm Dh DP 6. Calculate the shear stress (T) of the mud moving around the pipe: T = K (Ym) n 7. Calculate the pressure (Ps) decrease for the interval: Ps = 3.33 T x L Dh Dp 1000 B. Surge pressure around drill collars: 1. Calculate the estimated annular fluid velocity (v) around the drill collars: v = [ Dp 2 Dh 2 Dp 2 ] Vp 2. Calculate maximum pipe velocity (Vm): Vm = v x Convert the equivalent velocity of the mud due to pipe movement to equivalent flow rate (Q): Q = Vm [(Dh) 2 (Dp) 2 ] Calculate the pressure loss for each interval (Ps): Ps = x MW 0.8 x Q 1~8 x PV 0.2 x L (Dh Dp) 3 x (Dh + Dp) 1.8 C. Total surge pressures converted to mud weight: Total surge (or swab) pressures: psi = Ps (drill pipe) + Ps (drill collars) D. If surge pressure is desired: SP, ppg = Ps TVD, ft + MW, ppg E. If swab pressure is desired: SP, ppg = Ps TVD, ft MW, ppg Example: Determine both the surge and swab pressure for the data listed below: Data: Mud weight = 15.0 ppg Plastic viscosity = 60 cps Yield point = 20 lb/l00 sq ft Hole diameter = 7-7/8 in. Drill pipe OD = 4-1/2 in. Drill pipe length = 14,300 ft Drill collar OD = 6-1/4 in. Drill collar length = 700 ft Pipe running speed = 270 ft/min A. Around drill pipe: 1.Calculate annular fluid velocity (v) around drill pipe: v = [ (45) 2 ] v = [ ]

141 v = 253 ft/mm 2. Calculate maximum pipe velocity (Vm): Vm = 253 x 1.5 Vm = 379 ft/min NOTE: Determine n and K from the plastic viscosity and yield point as follows: PV + YP = φ300 reading φ300 reading + PV = φ600 reading Example: PV = 60 YP = = 80 (φ300 reading) = 140 (φ600 reading) 3. Calculate n: n = 3.32 log n = Calculate K: K = K = Calculate the shear rate (Ym) of the mud moving around the pipe: Ym = 2.4 x 379 ( ) Ym = Calculate the shear stress (T) of the mud moving around the pipe: T = (269.5) T = x T = Calculate the pressure decrease (Ps) for the interval: Ps = 3.33 (47.7) x 14,300 ( ) 1000 B. Around drill collars: Ps = x 14.3 Ps = 673 psi 1. Calculate the estimated annular fluid velocity (v) around the drill collars: v = [ ( ( ))] 270 v = ( )270 v = 581 ft/mm 2. Calculate maximum pipe velocity (Vm): Vm = 581 x 1.5 Vm = ft/mm 3. Convert the equivalent velocity of the mud due to pipe movement to equivalent flow-rate (Q): Q = ( )

142 Q = Q = Calculate the pressure loss (Ps) for the interval: Ps = x x x x 700 ( ) 3 x ( ) 1.8 Ps = Ps = psi C. Total pressures: psi = psi psi psi = psi D. Pressure converted to mud weight, ppg: ppg = psi ,000 ft ppg = 1.34 E. If surge pressure is desired: Surge pressure, ppg = 15.0 ppg ppg Surge pressure = ppg F. If swab pressure is desired: Swab pressure, ppg = 15.0 ppg 1.34 ppg Swab pressure = ppg 7. Equivalent Circulation Density (ECD) 1. Determine n: n = 3.32 log φ600 φ Determine K: K= φ n 3. Determine annular velocity (v), ft/mm: v = 24.5 x Q Dh 2 D 2 4. Determine critical velocity (Vc), ft/mm: Vc = (3.878 x 10 4 x K) (1 (2 n)) (n (2 n)) x ( 2.4 x 2n +1) MW Dh Dp 3n 5. Pressure loss for laminar flow (Ps), psi: Ps = ( 2.4v x 2n +1 ) n x KL. Dh Dp 3n 300 (Dh Dp) 6. Pressure loss for turbulent flow (Ps), psi: Ps = 7.7 x 10 5 x MW 0.8 x Q 1.8 x PV 0.2 x L (Dh Dp) 3 x (Dh + Dp)

143 7. Determine equivalent circulating density (ECD), ppg: ECD, ppg = Ps TVD, ft + 0MW, ppg Example: Equivalent circulating density (ECD), ppg: Data: Mud weight = 12.5 ppg Plastic viscosity = 24 cps Yield point = 12 lb/100 sq ft Circulation rate = 400 gpm Drill collar OD = 6.5 in. Drill pipe OD = 5.0 in Drill collar length = 700 ft Drill pipe length = 11,300 ft True vertical depth = 12,000 ft Hole diameter = 8.5 in. NOTE: If φ600 and φ300 viscometer dial readings are unknown, they may be obtained from the plastic viscosity and yield point as follows: = 36 Thus, 36 is the φ300 reading = 60 Thus, 60 is the φ600 reading. 1. Determine n: n = 3.321og n = Determine K: K = K = a. Determine annular velocity (v), ft/mm, around drill pipe: v = 24.5 x v = 207 ft/mm 3b. Determine annular velocity (v), ft/mm, around drill collars: v = 24.5 x a. Determine critical velocity (Vc), ft/mm, around drill pipe: v = 327 ft/mm Vc = (3.878 x 10 4 x ) (1 ( )) x ( 2.4 x 2(0.7365) + l) (0.7365) Vc = (1130.5) x ( ) Vc = 260 x Yc = 223 ft/mm 4b. Determine critical velocity (Yc), ft/mm, around drill collars: Vc = (3.878 x 10 4 x ) (1 ( )) x ( 2.4 x 2(0.7365) + l) (0.7365) Vc = ( ) x (1.343) ( ( )) ( ( )) 142

144 Vc = 260 x Vc = 309 ft/mm Therefore: Drill pipe: 207 ft/mm (v) is less than 223 ft/mm (Vc), Laminar flow, so use Equation 5 for pressure loss. Drill collars: 327 ft/mm (v) is greater than 309 ft/mm (Vc) turbulent flow, so use Equation 6 for pressure loss. 5. Pressure loss opposite drill pipe: Ps = [ 2.4 x 207 x 2 (0.7365)+ 1 ] x x 11, (0.7365) 300( ) Ps = [ 2.4 x 207 x 2(0.7365) + 1 ] x x 11, ( ( ) Ps = (141.9 x ) x Ps = x Ps = psi 6. Pressure loss opposite drill collars: Ps = 7.7 x 10 5 x x x x 700 ( ) 3 x ( ) 1.8 Ps = x Ps = 35.4 psi Total pressure losses: psi = psi psi psi = psi 7. Determine equivalent circulating density (ECD), ppg: ECD, ppg = psi ,000 ft ppg ECD = ppg 9. Fracture Gradient Determination - Surface Application Method 1: Matthews and Kelly Method F = P/D + Ki σ/d where F = fracture gradient, psi/ft σ = matrix stress at point of interest, psi Ki = matrix stress coefficient, dimensionless P = formation pore pressure, psi D = depth at point of interest, TVD, ft Procedure: 143

145 1. Obtain formation pore pressure, P, from electric logs, density measurements, or from mud logging personnel. 2. Assume 1.0 psi/ft as overburden pressure (S) and calculate σ as follows: σ = S P 3. Determine the depth for determining Ki by: D = σ From Matrix Stress Coefficient chart, determine Ki: Figure 5-1. Matrix stress coefficient chart 144

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